Morphometric aspects of the human hypoglossal nerve in adults and the elderly

AIM

Perform a morphometric analysis of the myelinic fibers of the right hypoglossal nerve, in two age groups; to verify quantitative changes as a result of the aging process.

STUDY DESIGN

Anatomic.

MATERIAL AND METHOD

A 1 cm fragment of the right hypoglossal nerve was collected from 12 male corpses without any medical history of diseases such as: diabetes, alcoholism, and malignant neoplasia. The sample was divided in two groups: group with six corpses under sixty years old (adult), and another group with six corpses sixty years old or above (elderly). The material was fixed at 2.5% glutaldehyde and 2% paraformaldehyde solution; post-fixed at 2% osmium tetroxide; dehydrated with increasing ethanol concentrations, and included in epoxy resin. Semi-thin sections of 0.3 microm were obtaining, colored in 1% toluidine blue, and evaluated with light microscope combined with image analyzing system. The following morphometric data were quantified: intraperineural transversal section area, number, and diameter of the myelinic fibers.

RESULTS

The intraperineural area of the hypoglossal nerve was similar in both age groups (p=0.8691). The average area in the adult group was 1.697 mm2 and in the elderly group it was 1.649 mm2. The total number of myelinic fibers of the hypoglossal nerve was similar in both age groups (p=0.9018). The adult group presented an average of 10,286 +/- 2,308 myelinic fibers, and the elderly group presented an average of 10,141 +/- 1,590 myelinic fibers. A bimodal distribution of the myelinic fibers was observed, with a significant peak on the 9 microm fibers, and another smaller peak on the 2 microm fibers.

CONCLUSION

The intraperineural area and the total number of myelinic fibers of the right hypoglossal nerve are similar in both age groups.

Ultrastructural Identification of a Sympathetic Component in the Hypoglossal Nerve of Hamsters Using Experimental Degeneration and Horseradish Peroxidase Methods

We employed experimental degeneration, tract-tracing with wheatgerm agglutinin conjugated with horseradish peroxidase (WGA-HRP) and electron microscopy to explore the postganglionic sympathetic fibers in the hypoglossal nerve of hamsters. Quantitative results of normal untreated animals at the electron microscopic level showed the existence of unmyelinated fibers, which made up about 20% of the total fibers in the nerve, being more numerous on the left side. The nerve fibers were preferentially distributed at the periphery of the nerve. Following superior cervical ganglionectomy, most of the unmyelinated fibers underwent degenerative changes. Tract-tracing studies showed that some of the unmyelinated fibers were labeled by WGA-HRP injected into the superior cervical ganglion (SCG). It is suggested that the unmyelinated fibers represent the postganglionic sympathetic fibers originated from the SCG.

Changes of high-affinity choline transporter CHT1 mRNA expression during degeneration and regeneration of hypoglossal nerves in mice

The high-affinity choline transporter CHT1 works for choline uptake in the presynaptic terminals of cholinergic neurons. We examined its expression in the hypoglossal nucleus after unilateral hypoglossal nerve transection in mice by fluorescent in situ hybridization. One week after axotomy, CHT1 mRNA expression was lost in all hypoglossal motoneurons in the lesioned side. Two weeks after axotomy, CHT1 mRNA started to be re-expressed in a few motoneurons that recovered connections to tongue muscles as revealed by retrograde labeling with Fast Blue. After 4 weeks, most of axotomized hypoglossal motoneurons were reconnected and re-expressed CHT1 mRNA as strongly as control neurons, and the regenerating cholinergic axons established mature neuromuscular junctions. These results suggest that the establishment of motor innervation is critical for CHT1 mRNA expression in hypoglossal neurons after axotomy.

Synaptic remodeling in the nucleus ambiguus following vagal–hypoglossal nerve anastomosis in the cat

We reported recently the occurrence of a massive and selective elimination of synaptic boutons on motoneurons in the dorsal motor nucleus of the vagus (DMV) in the cat following vagal-hypoglossal nerve anastomosis (VHA) [J. Comp. Neurol. 458 (2003) 195]. This study was aimed to explore the synaptic reorganization in the other major nucleus associated with the vagus, namely, the nucleus ambiguus (NA) following the same treatment. In view of the tremendous difference in function, the NA and DMV are considered to be two ideal nuclei for explanatory studies seeking to elucidate how VHA could induce different plasticity of brainstem neurons influenced by the newly reestablished neural pathway. The present results showed that the vagal efferent neurons in the NA had responded to VHA in a different manner compared with those in the DMV. Firstly, the numbers of axon terminals containing round (R), round with dense-cored (R+D), pleomorphic (P) or flattened (F) synaptic vesicles contacting the NA motoneurons were markedly increased at 500-day postoperation, the longest reinnervation interval. The percent increases in the synapse frequency for R, R+D, P and F boutons were 8.6%, 274.4%, 238.3% and 400.0%, respectively. Secondly, the formation of astroglial ensheathment around the motoneurons in the DMV following VHA was not evident in the NA. Another striking difference was the extensive dendritic sprouting of the NA neurons as opposed to the dendritic retraction of the DMV neurons as shown by a significant increase in distal dendrites of NA motoneurons. The different modes of neural remodeling between NA and DMV may be attributed to the unique nature of the two nuclei to structures they normally supply and their different compatibility with the newly innervated target, viz. tongue skeletal musculature.

Genioglossal hypoglossal motoneurons contact substance P-like immunoreactive nerve terminals in the cat: a dual labeling electron microscopic study

This study investigated the synaptic interactions between hypoglossal motoneurons that project to the genioglossus muscle and substance P (SP) containing immunoreactive nerve terminals. Cholera toxin B conjugated to horseradish peroxidase (CTB-HRP) was injected into the right half of the genioglossus muscle in four anesthetized cats. Two days later, the animals were perfused with acrolein fixative. Tetramethylbenzidine (TMB) was the chromogen used to detect retrogradely labeled cells containing CTB-HRP. The tissues were then processed for immunocytochemistry using an antiserum raised against SP with diaminobenzidine (DAB) as the chromogen. At the light microscopic level, labeled cells were observed primarily ipsilaterally in ventral and ventrolateral subdivisions of the hypoglossal nucleus. The majority of these labeled cells were observed at the level of the area postrema. At the electron microscopic level, SP-like immunoreactive nerve terminals formed synaptic contacts with retrogradely labeled dendrites and perikarya. Nineteen percent of the terminals that contacted retrogradely labeled cells contained SP. These are the first ultrastructural studies demonstrating synaptic interactions between protruder hypoglossal motoneurons and SP terminals. These studies demonstrate that hypoglossal motoneurons which innervate the major protruder muscle of the tongue, the genioglossus muscle, may be modulated by SP. Thus, SP may play a role in the control of protrusive movements of the tongue acting via neurokinin receptors.

Ultrastructural features of synapse from dorsal parvocellular reticular formation neurons to hypoglossal motoneurons of the rat

The dorsal parvocellular reticular formation (PCRt) receives projection of the trigeminal mesencephalic nucleus neurons. It contains the dorsal group of interneurons that integrate and coordinate activity of the oral motor nuclei. Ultrastructural features of synaptic connection from the dorsal PCRt neurons to the motoneurons of the hypoglossal nucleus (XII) were examined at both the light and electron microscopic levels in rats. Biotinylated dextran amine (BDA) was initially iontophoresed into the dorsal part of PCRt unilaterally. Seven days later horseradish peroxidase (HRP) was injected into the body of the tongue. After histochemical reaction for visualization of HRP and BDA, the BDA-labeled fibers and terminals were seen distributing bilaterally in XII with ipsilateral predominance. BDA-labeled terminals were closely apposed upon HRP retrogradely labeled somata and dendrites of the XII motoneurons. A total of 1408 BDA-labeled boutons were examined ultrastructurally, which had mean size of 1.22+/-0.37 microm in diameter. Five hundred-ninety three of these boutons in both the ipsilateral (n=401) and contralateral (n=192) XII were seen to synapse on both the dendrites and somata of HRP-labeled motoneurons. The vast majorities of synapses were axodendritic (98%, 580/593), while 2% of them were axosomatic. Of the 1408 BDA-labeled boutons, 69.6% of them were S-type boutons containing small clear and spherical synaptic vesicles and 30.4% of them were PF-type boutons containing pleomorphic and flattened synaptic vesicles. Approximately 64% of synapses between BDA-labeled boutons and HRP-labeled motoneurons were asymmetric, and 33% of synapses were symmetric. No axoaxodendritic or axoaxosomatic synaptic triad was observed. The present study illustrated the anatomical pathway and synaptological characteristics of neuronal connection between the dorsal PCRt premotor neurons and the XII motoneurons. Its functional significance in coordinating activity of XII motoneurons during oral motor behaviors has been discussed.

Morphological changes in frog mast cells induced by nerve stimulation in vivo

We investigated at both histochemical and ultrastructural levels the effects of unilateral electrical stimulation in vivo of the frog hypoglossal nerve on the mast cells (MCs) within the nerve fascicles and among the axon terminals. The right ventral root of the hypoglossal nerve in different experiments was stimulated respectively for 1, 3, 5, 10 min with over-threshold stimuli (10 Hz; 2 ms duration). The stimulations at 3, 5 and 10 min caused a progressive degranulation and histochemical and ultrastructural changes of the MCs at the stimulated side. The morphological changes consisted of the loss of Alcian Blue secretory content and of a progressive release of safranin+ secretory granules, depending upon duration of stimulation. The ultrastructural study showed that granules are discharged whole into the microenvironment or may release their content through exocytosis. A functional relationship between nerve and MCs is also suggested by the close anatomical association between MCs and pre-terminal axons observed following 10 min of hypoglossal stimulation. No changes in MC morphology occurred after 1 min of electrical stimulation. The results suggest that active cholinergic fibres can modulate MC secretion.

Axonal projections and synapses from the supratrigeminal region to hypoglossal motoneurons in the rat

Neural circuits from the supratrigeminal region (Vsup) to the hypoglossal motor nucleus were studied in rats using anterograde and retrograde neuroanatomical tracing methodologies. Iontophoretic injection of 10% biotinylated dextran amine (BDA) unilaterally into the Vsup anterogradely labeled axons and axon terminals bilaterally in the hypoglossal nucleus (XII) as well as other regions of the brainstem. In the ipsilateral XII, the highest density of BDA labeling was found in the dorsal compartment and the ventromedial subcompartment of the ventral compartment, where BDA labeling formed a dense, patchy distribution. Microinjection of 20% horseradish peroxidase (HRP) ipsilaterally or bilaterally into the tongue resulted in retrograde labeling of XII motoneurons confined to the dorsal and ventral compartments of the hypoglossal motor nucleus. Under light microscopical examination, BDA-labeled terminals were observed closely apposing the somata and primary dendrites of HRP-labeled hypoglossal motoneurons. Two hundred and sixty-five of these BDA-labeled terminals were examined at the ultrastructural level. One hundred and twelve BDA-labeled axon terminals were observed synapsing with either the somata (39%, 44/112) or the large or medium-size dendrites (61%, 68/112) of retrogradely labeled hypoglossal motoneurons. Axon terminals containing spherical vesicles (S-type) formed asymmetric synapses with HRP-labeled hypoglossal motoneuron dendrites. In contrast to this, F(F)-type axon terminals, containing flattened vesicles, formed symmetric synapses with both the somata and dendrites of HRP-labeled hypoglossal motoneurons with a preponderance of the contacts on their somata. Axon terminals containing pleomorphic vesicles (F(P)-type) were noted forming both symmetric and asymmetric synapses with HRP-labeled hypoglossal motoneuron somata and dendrites. The present study provides anatomical evidence of neuronal projections and synaptic connections from the supratrigeminal region to hypoglossal motoneurons. These data suggest that the supratrigeminal region, as one of the premotor neuronal pools of the hypoglossal nucleus, may coordinate and modulate the activity of tongue muscles during oral motor behaviors.

Different astroglial reaction between the vagal dorsal motor nucleus and nucleus ambiguus following vagal-hypoglossal nerve anastomosis in cats

The dorsal motor nucleus of the vagus (DMV) and nucleus ambiguus (NA) were both traced with horseradish peroxidase (HRP) retrograde labelling technique after vagal-hypoglossal nerve anastomosis (VHA). By light microscopy, reinnervation of the new target, viz. tongue skeletal musculature, by DMV and NA was established at 22 days postoperation (dpo) as shown by the neuronal labelling with HRP. Ultrastructurally, signs of retrograde degeneration occurred in some DMV and NA neurons between 3 and 25 days after VHA. The incidence of darkened dendrites, an early sign of dendritic loss, was more common in the DMV compared to the NA. Accompanying the neuronal alteration were drastic astrocytic reactions in the DMV, but not in the NA. Between 3 and 7 dpo, the astrocytes in the DMV showed extensively hypertrophied processes and by 22 dpo, the somata and dendrites of HRP-labelled DMV neurons, but not NA's, appeared to be delineated by the increased lamellar astrocytic processes. Such a feature was sustained throughout the remaining postoperative intervals up to 500 dpo. It is concluded that the DMV motoneurons being autonomic in nature are probably not conducive to the newly acquired target organ. Hence, the insulation of the regenerating DMV motoneurons by the astroglial ensheathment would be vital in the neuronal remodelling and reconstruction of the vagal-hypoglossal pathway.

Ultrastructural evidence of calcium involvement in experimental autoimmune gray matter disease

Experimental studies have suggested that increased calcium and inappropriate calcium handling by motoneurons might have a significant role in motoneuron degeneration. To further define the involvement of calcium in motoneuron loss we used the oxalate-pyroantimonate technique for calcium fixation and monitored the ultrastructural distribution of calcium in spinal motoneurons in experimental autoimmune gray matter disease (EAGMD). In cervical and hypoglossal motoneurons from animals with relatively preserved upper extremity and bulbar function, increased calcium precipitates were present in the cytoplasm as well as in mitochondria, endoplasmic reticulum and Golgi complex without significant morphologic alterations. In surviving lumbar motoneurons of animals with hindlimb paralysis, however, there was massive morphological destruction of intracellular organelles but no significant accumulation of calcium precipitates. These findings suggest that altered calcium homeostasis is involved in motoneuron immune-mediated injury with increased calcium precipitates early in the disease process and decreased to absent calcium precipitates later in the pathogenesis of motoneuron injury.

Substance P in the hypoglossal nucleus of the rat

The distribution of substance P (SP)-containing synaptic terminals in the hypoglossal nucleus (XII) of adult rats was examined by retrograde peroxidase labelling and immunocytochemistry. From the location of peroxidase injections into the tongue and of labelled neurones in the ventral lamina of XII, motor neurones that supply intrinsic vertical, longitudinal and transverse fibres as well as the extrinsic muscle genioglossus appear to have been labelled. SP-containing terminals were found making contact, and sometimes dual synapses, with unlabelled neuronal dendrites but not with retrogradely labelled somata or dendrites. These findings suggest that SP terminals may contact dendrites of interneurones or of neurones supplying other extrinsic muscles located in the anterior part of the tongue. Dual SP-containing synapses between XII motor neurones may be the means by which tongue muscle fibres are recruited and their function synchronized.

Quantitative analysis of the dendritic architectures of cat hypoglossal motoneurons stained intracellularly with horseradish peroxidase

Little is known about the dendritic architecture of cat hypoglossal motoneurons. Thus, the present study was done to provide quantitative descriptions of hypoglossal motoneurons and to determine correlations between dendritic size parameters by using the intracellular horseradish peroxidase (HRP) injection technique in the cat. Twelve hypoglossal motoneurons stained with HRP were antidromically activated by stimulation applied to the medial branch of hypoglossal nerve. Eight (type I) and four (type II) of the 12 motoneurons were located in the ventral and dorsal parts of the ventromedial subnucleus of hypoglossal nucleus, respectively. The somatodendritic morphology of the two types of neurons was remarkably different, especially in the dendritic arborization pattern. The type I neurons established an egg-shaped dendritic tree that was distributed through the nucleus to the reticular formation; the type II dendritic tree was confined within the nucleus and presented a rostrocaudally oriented, mirror-image, fan-shape appearance. The total dendritic area and length and the number of terminations and branch points were significantly larger for type I than for type II neurons. For the two types of neuron, there was a positive correlation between stem dendritic diameter and several dendritic size parameters. Although the slopes of the regression lines were slightly different between the two, these were not statistically significant. The present study provides evidence that hypoglossal motoneurons located in the ventromedial subnucleus could be divided into two types according to the dendritic arborization pattern and quantitative analysis of the dendritic tree and according to neuronal location and suggests that the two types of hypoglossal motoneurons can be viewed as intrinsically distinct cell types: type I and type II, which innervate extrinsic and intrinsic muscles, respectively. In addition, the morphometric analysis made it possible to estimate the size of the dendritic tree by measuring the stem dendritic diameter.

Ultrastructure of enkephalin- and substance P-immunoreactive axon terminals in the hypoglossal nucleus of the chicken

The morphology and distribution of leucine-enkephalin (LENK)- and substance P (SP)-containing axon terminals in the hypoglossal nucleus of the chicken was investigated immunocytochemically at the electron microscopic level. The major findings of the present study were as follows: 1) Both LENK- and SP-immunoreactive (IR) profiles including unmyelinated axons, varicosities and axon terminals were found throughout the hypoglossal nucleus. 2) LENK-IR profiles without synapses (preterminal axons and varicosities) were observed more frequently (66%) than LENK-IR synaptic profiles (34%). In contrast, SP-IR synaptic terminals were seen more often (68%) than SP-IR terminals without synapses (32%). 3) Both LENK- and SP-IR synaptic terminals ending on dendrites were more numerous (83% and 94%, respectively) than those making synapses on somata (17% and 6%, respectively). 4) The average diameter of SP-IR synaptic terminals were significantly larger than that of LENK-IR ones. 5) Both LENK- and SP-IR synaptic terminals contained numerous small clear vesicles and several large dense-cored vesicles (LDV). Although both LENK- and SP-IR synaptic terminals contained LDV consistently, SP-IR synaptic terminals contained significantly more LDV than LENK-IR types. 6) Postsynaptic dense bodies (Taxi bodies) were seen more frequently in SP-IR synaptic terminals than in LENK-IR ones. These findings confirm both LENK and SP innervation in the hypoglossal nucleus and suggest a functional role as neuromodulator for the two neuropeptides in tongue control.

Autoradiographic localization of neurotransmitter binding sites in the hypoglossal and motor trigeminal nuclei of the rat

The hypoglossal and motor trigeminal nuclei contain somatic motoneurons innervating the tongue, jaw, and palate. These two cranial motor nuclei are myotopically organized and contain neurotransmitter binding sites for thyrotropin-releasing hormone, substance P, and serotonin. Quantitative autoradiography was used to localize thyrotropin-releasing hormone, substance P, and serotonin-1A and serotonin-1B binding sites in the hypoglossal and motor trigeminal nuclei and to relate the relative distributions of these binding sites to the myotopic organizations of the two nuclei. In the hypoglossal nucleus, high-to-moderate concentrations of all four binding sites were present in the dorsal and ventromedial subnuclei, whereas low concentrations were noted in the ventrolateral subnucleus. In the motor trigeminal nucleus, high concentrations of serotonin-1B, moderate densities of thyrotropin-releasing hormone, and low levels of substance P and serotonin-1A binding sites were present in both the ventromedial and dorsolateral subnuclei. These observations demonstrate that neurotransmitter binding sites in the hypoglossal and motor trigeminal nuclei are heterogeneously localized and that their distributions correspond to the previously described myotopic organizations of each nucleus.

Nimodipine maintains in vivo the increase in GFAP and enhances the astroglial ensheathment of surviving motoneurons in the rat following permanent target deprivation

Facial and hypoglossal nerves were resected unilaterally in a total of 108 rats. Rats were divided into two groups; one group received standard food pellets (placebo), the other received food pellets containing the Ca(2+)-blocking agent nimodipine. The expression of glial fibrillary acidic protein was examined in paraffin sections of the brainstem using light microscopical immunocytochemistry, and the degree of glial process ensheathment of the surviving neuronal perikarya in the hypoglossal and facial nuclei quantified on electron micrographs. Up to 28 days post-axotomy no differences in glial fibrillary acidic protein-immunoreactivity were observed between placebo and nimodipine-treated animals. By 42-56 days, glial fibrillary acid protein-immunoreactivity was stronger in the nimodipine treated animals and by 112 days, glial fibrillary acid protein-immunoreactive astrocytes occurred only in nimodipine-treated animals. Thin astrocytic processes were seen to ensheath neurons in both placebo and nimodipine-treated animals. By 28 days post axotomy, lesioned neurons in nimodipine treated animals were covered by a mean of 2.6 (hypoglossal) and 2.9 (facial nucleus) astrocytic lamellae, compared with 1.7 lamellae in the placebo group. This relatively greater ensheathment of hypoglossal and facial neurons was maintained up to 112 days post-lesion, but reduced in the placebo-treated group to approximately 1.4 lamellae. It is concluded that nimodipine enhances the formation of astrocytic lamellae on lesioned neurons and that this process may be associated with a protective role for activated astrocytes directed towards motoneurons suffering from permanent target-deprivation.

Muscle representation within the hypoglossal nucleus of the chicken studied by means of horseradish peroxidase

The distribution in the chicken of motoneurons innervating the hyolingual muscles, i.e. the Mm. hyoglossus rostralis (HR), hyoglossus obliquus (HO), ceratoglossus (CG), interceratobranchialis (CB), stylohyoideus (YH), serpihyoideus (PH) and cricohyoideus (CR), and the laryngotracheal muscles, comprising the Mm. tracheolateralis (TL), cleidohyoideus (CL) and sternotrachealis (ST), was examined by retrograde transport of horseradish peroxidase conjugated with wheat-germ agglutinin. Labelled motoneurons are only found in the hypoglossal nucleus. The rostrocaudal distributions of motoneurons projecting to hyolingual muscles are restricted in the hypoglossal nucleus cranial to the obex, and those projecting to laryngotracheal muscles are distributed in the more caudal part of hypoglossal nucleus. Detailed analysis of the data showed that the most rostrally positioned motoneurons in the hypoglossal nucleus supplied to the PH, followed by the CG, CB, HR, YH, HO, CR, TL, CL and ST in that order, overlapping each other. In the hypoglossal nucleus motoneurons innervating the PH and YH have the smallest perikarya. Of the motoneurons in the hypoglossal nucleus, those supplying the laryngotracheal muscles (CL and TL) have the largest perikarya. Motoneurons innervating the other muscles are intermediate in size.

Synaptic interactions of retrogradely labeled hypoglossal motoneurons with substance P-like immunoreactive nerve terminals in the cat: a dual-labeling electron microscopic study

This study has investigated the synaptic interactions between hypoglossal motoneurons and substance P (SP)-immunoreactive terminals. Cholera toxin B conjugated to horseradish peroxidase was injected into the tip of the tongue on the right side of six ketamine-anesthetized cats. Two to five days later, the animals were killed. Cells containing HRP were labeled with a histochemical reaction utilizing tetramethylbenzidine (TMB) as the chromogen. TMB forms crystalline reaction products that are very distinct at the electron microscopic level. The tissues were then processed for immunocytochemistry using an antiserum against SP. The chromogen used in this case, diaminobenzidine, yields amorphous reaction products. At the light microscopic level, labeled cells were observed primarily ipsilaterally in both intermediate and ventrolateral subdivisions of the hypoglossal nucleus. The majority of these labeled cells were seen at the level of obex. At the electron microscopic level, both asymmetric and symmetric synapses were observed. SP-immunoreactive nerve terminals formed asymmetric synapses with labeled dendrites and symmetric synapses with labeled perikarya. SP-labeled terminals also synapsed on unlabeled dendrites and somata. These are the first ultrastructural studies demonstrating synaptic interactions between hypoglossal motoneurons and SP terminals. These studies demonstrate that hypoglossal motoneurons that innervate intrinsic tongue muscles are modulated by SP and that SP may play a role in the control of fine movements of the tongue.

Intracranial hypoglossal neurinoma without preoperative hypoglossal nerve paresis--case report

A 46-year-old female presented with an intracranial hypoglossal neurinoma manifesting only as spasticity in the lower extremities without hypoglossal nerve paresis. Magnetic resonance imaging greatly aided in the early detection of the tumor with this atypical presentation. Unilateral suboccipital craniotomy with resection of the occipital condyle allowed us to approach the tumor in front of the medulla from an inferolateral direction and to remove it successfully. We emphasize the need to pack dead space with fatty tissue to prevent cerebrospinal fluid leakage.

The progression of deafferentation as a retrograde reaction to hypoglossal nerve injury

This study examined the fate of axon terminals of one of the major sources of hypoglossal afferents, the spinal V nucleus, after XIIth nerve resection in adult Sprague-Dawley rats. In order to anterogradely label trigemino-hypoglossal projections, small quantities of horse radish peroxidase were pressure-injected into the ipsilateral dorsal (mandibular) portion of the spinal V nucleus two days before the animals were killed. Survival periods ranged from 5 to 33 days after nerve injury (dpo). Axonal injury produced relative changes in the association of labelled axon terminals to structures in the hypoglossal nucleus on the injured side. The proportion of horse radish peroxidase-labelled spinal V nucleus terminals with spherical vesicles (S-terminals) that were unapposed to hypoglossal somata or dendrites increased rapidly and reached maximal levels by 11 dpo. By contrast, the isolation of labelled terminals with pleomorphic/flattened vesicles (P/F-terminals) from postsynaptic structures began later, advanced at a slower rate and did not attain maximal levels until 20 dpo. S-terminals not apposed to neuronal cell parts increased at a rate of 2.2 times greater than unapposed P/F-terminals. In addition, at peak levels, the proportion of labelled S-terminals that were detached from somata and dendrites was significantly greater than unapposed, labelled P/F-terminals. Axotomy did not alter the caliber of the labelled axon terminals. However, by 29 days after axotomy, the average diameter of dendrites remaining in contact with SPVN terminals was 1/3 the diameter of dendrites of uninjured neurons apposed to labelled axon terminals. These findings provide the morphological correlate for physiological and pharmacological evidence that the effectiveness of excitatory and inhibitory synapses are down-regulated in a coordinated manner after hypoglossal nerve injury.

Sudden infant death syndrome: increased number of synapses in the hypoglossal nucleus

The medulla was sampled from nine cases of sudden infant death syndrome (SIDS) and from six age-matched control cases without neurological disease. Morphometric analyses were performed on serial Nissl sections through the hypoglossal nucleus on the left side of the medulla. The total volume of the nucleus and both the numerical density (Nv, cells per mm3) and total number of neurons were measured. Tissue from the remaining hypoglossal nucleus was prepared for electron microscopy using the ethanolic phosphotungstic acid method to stain synaptic contacts. Stereological analyses were performed to determine the Nv and total number of synapses. Total volume of the hypoglossal nucleus was significantly greater (36%) in SIDS cases than in controls. The Nv of neurons was significantly less than in controls (28%), although the total number of neurons did not differ significantly. The mean profile area of motor neuron cell bodies was significantly greater (30%) in SIDS cases, with no differences in the mean profile areas for interneurons or glia. The Nv of synapses did not differ significantly between SIDS cases and controls, although the total number of synapses was greater (61%) in SIDS. These abnormalities in growth indicate a greater volume of neuropil in a hypoglossal nucleus containing a normal complement of neurons. The greater number of synapses in SIDS cases is consistent with a failure to eliminate normally extraneous synapses during early development.

Ultrastructure of spinal relay of hypoglossal afferents to the parabrachial nucleus

Wheat germ agglutinin-conjugated horseradish peroxidase (WGA-HRP) injection into the hypoglossal nerve mainly resulted in retrograde labeling in the superior ganglia of the glossopharyngeal and vagal nerves ipsilaterally. Anterogradely labeled fibers were found in lamina I of the ipsilateral upper cervical spinal cord with a few distribution to laminae IV-V and VII-VIII. WGA-HRP injection into the PBN revealed intensive labeling of lamina I neurons of the upper cervical spinal cord ipsilaterally. These light microscopic observations appear to indicate the hypoglossal sensory inputs to the PBN through the spinal cord. In order to investigate the synaptic nature of this spinal relay, electron microscopic observations were carried out on lamina I of the first and second cervical spinal cord after cutting the hypoglossal nerve and WGA-HRP injection into the PBN in the same animal. The spinoparabrachial projection neurons were demonstrated to show a low cytoplasmic/nuclear ratio and have an oval or deeply indented nucleus with a centrally located nucleolus. Furthermore, dark and light type degenerating fibers were observed to make synaptic contacts with HRP-labeled somata and dendritic profiles.

Functional and histological evaluation of the facial nerve in patients who have undergone hypoglossal-facial nerve anastomosis after removal of cerebellopontine angle tumors

Facial nerve specimens removed from ten patients who underwent hypoglossal-facial nerve anastomosis for facial palsy following removal of cerebellopontine angle tumors were studied histologically. Facial nerve function prior to the anastomosis surgery and the degree of postoperative functional recovery were compared with the histological results. The recovery of facial palsy after the anastomosis surgery was excellent or satisfactory in nine patients and the endoneurium within the nerve fascicles was well-preserved. The recovery of facial palsy was poor in one patient who had severe fibrosis of the endoneurium. The histological and ultrastructural features of the facial nerve were closely related to the occurrence of facial palsy prior to tumor removal, the status of the nerve after tumor removal, and the interval between tumor removal and anastomosis surgery. Based on these histological and functional relationships, the timing and indications for anastomosis surgery are discussed.

[Development and cell differentiation in the nucleus nervi hypoglossi in cows]

Based upon light- and electron-microscope examinations, the ontogenetic development of the nucleus of cranial nerve XII is documented. At 1-cm crown-rump length (CRL), the caudal pole of the nucleus nervi hypoglossi forms a uniform cell column with the cornu ventrale of the spinal cord. During this period, its caudal area shows signs of cellular degeneration. From 3.5 cm CRL onward, all nuclear groups can be identified. At 53 cm CRL, they correspond to the pattern as described in the adult brain. Electron-optically, at 2.5 cm and 3.6 cm CRL, the nucleus of cranial nerve XII exhibits a close relationship to the matrix layer which consists of elements of dark nuclei. The hypoglossus nucleus is composed of dark and light cell types. It is the latter type that represents the presumptive neuron; it shows an increased ultrastructural differentiation from 2.5 cm CRL onward.

Increased production of ubiquitin mRNA in motor neurons after axotomy

Ubiquitin targets proteins for attack by certain proteolytic enzymes, but the ubiquitinated cytoplasmic inclusions seen in some chronic neurodegenerative diseases may indicate the occurrence of reparative rather than destructive metabolic events. We have examined the production of ubiquitin in motor neurons of the rat's left hypoglossal nucleus after transection of their axons in circumstances that favour or prevent axonal regeneration. One week after axotomy, in situ hybridization with a radiolabelled cRNA probe revealed a twofold increase in the ubiquitin mRNA content of neurons with regenerating axons (nerve crushed) but not significant change when axonal regeneration had been prevented (nerve transected and ligated). After 2 weeks, ubiquitin mRNA was elevated to about 1.5 times the contralateral control level, regardless of the type of nerve injury, and by 4 weeks there were no longer any differences between the left and right sides. Despite the increased transcription, axotomy was not followed by any change in the quantity of ubiquitin-immunoreactive material in the nuclei or perikarya of hypoglossal neurons as measured by video image analysis of immunohistochemically stained sections. We suggest that ubiquitin is synthesized in neuronal cell bodies and transported into their axons, and that ubiquitin-mediated proteolysis is a metabolic process involved in the elongation of regenerating axons.

Regeneration of facial nerve after hypoglossal facial anastomosis: an animal study

Hypoglossal-facial nerve anastomosis was carried out in 20 adult guinea pigs. Electromyographic responses of orbicularis oculi muscle evoked by blink reflex were recorded 2, 4, and 6 months after surgery. Then the anastomotic site was reopened, and a segment of buccal branch and the anastomotic trunk were resected for detailed histologic study. Regenerated axons were counted and the cross-sectional area of axons and fasciculi was measured. Data obtained from both blink reflex measurement and histologic study demonstrate a good quality of regeneration of the facial nerve from the hypoglossal nerve completed 6 months after the operation. In addition a new nerve bundle was regenerated from the proximal stump of the facial nerve connecting to the anastomotic site in 80% of the animals. Postoperative change in innervation pattern of the facial nerve was also illustrated.

Differential response of neutral endopeptidase 24.11 ("enkephalinase"), and cholinergic and opioidergic markers to hypoglossal axotomy

Neutral endopeptidase 24.11 (NEP; "enkephalinase") may inactivate a number of centrally active neuropeptides including the enkephalins and substance P. In most areas of the central nervous system, the cell types which express NEP activity are not known. The hypoglossal nucleus (N.XII) was selected as a model system to characterize the cytochemical localization of NEP. The effect of hypoglossal nerve axotomy upon the distribution of NEP activity in the hypoglossal nucleus was compared to the effect upon cholinergic markers, the mu opiate receptor, and the enkephalins. By use of a fluorescence histochemical method, NEP was localized at all levels of N.XII to the soma and proximal processes of the majority of the apparent motor neurons in the nucleus. Fluorescent double-labeling studies revealed the presence of numerous enkephalinergic varicosities which localized to the neuropil surrounding NEP-stained motor neurons. To determine whether NEP was synthesized by these motor neurons, 18 rats received a unilateral transection of the hypoglossal nerve. A pronounced decrease in NEP staining in N.XII was observed on the operated side as early as 3 days following axotomy. This decrease persisted at all levels of the nucleus for about 5 weeks. By 7 weeks, the staining between the control and operated sides was indistinguishable. By contrast, there was no apparent change in the density or distribution of enkephalin-immunoreactive varicosities in five animals examined 6 to 32 days following axotomy. Radioligand binding of [3H]DAMGO to the mu-opiate receptor in N.XII was studied in 20 animals by quantitative autoradiography at 2, 6, and 11 days after axotomy. No significant changes in the level of radioligand binding to the mu-receptor were detected in response to axotomy. In contrast to the opiate system, the cholinergic enzymes choline acetyltransferase, acetylcholinesterase, and pseudocholinesterase showed a coordinate decrease in motor neuron-associated staining on the operated side of N.XII at 3, 6, and 11 days following axotomy which paralleled the decrease in NEP staining. By contrast, the lysosomal enzyme marker, acid phosphatase, showed a pronounced increase in staining on the operated side. The results of this study are consistent with the synthesis of NEP by cholinergic N.XII motor neurons and indicates that the enkephalins and NEP in N.XII are closely associated, but derive from separate neuronal populations. The widespread overlap in the distribution of NEP-stained motor neurons and enkephalinergic varicosities in N.XII provides additional anatomical support for a potential role for NEP in the inactivation of centrally active enkephalins.(ABSTRACT TRUNCATED AT 400 WORDS)

Subcellular distribution of ryanodine receptor-like and calcium ATPase-like immunoreactivity in brainstem and cerebellar neurones of rat and guinea pig

Monoclonal antibodies against ryanodine receptor (5C3) and calcium ATPase (D12) of skeletal muscle sarcoplasmic reticulum were used in an immunoelectron microscopic study of cerebellar Purkinje cells and neurons of the hypoglossal and dorsal motor nuclei of the vagus (DMV) from rat and guinea-pig. All neurones were labelled with D12 and all, except rat DMV, labelled with 5C3. Most labelling was on smooth endoplasmic reticulum within 500 nm of the plasmalemma where Ca(2+)-activated Ca2+ release would rapidly increase cytosolic calcium following a small Ca2+ influx across the plasmalemma.

Morphology of developing rat genioglossal motoneurons studied in vitro: changes in length, branching pattern, and spatial distribution of dendrites

The aim of this study is to describe the postnatal change in dendritic morphology of those motoneurons in the hypoglossal nucleus that innervate the genioglossus muscle. Forty genioglossal (GG) motoneurons from four age groups (1-2, 5-6, 13-15, and 19-30 postnatal days) were labeled by intracellular injection of neurobiotin in an in vitro slice preparation of the rat brainstem and were reconstructed in three-dimensional space. The number of primary dendrites per GG motoneuron was approximately 6 and remained unchanged with age. The development of these motoneurons from birth to 13-15 days was characterized by a simplification of the dendritic tree involving a decrease in the number of terminal endings and dendritic branches. Motoneurons lost their 6th-8th order branches, in parallel with an elongation of their terminal dendritic branches maintaining the same combined dendritic length. The elongation of terminal branches was attributed to both longitudinal growth and the apparent lengthening caused by resorption of distal branches. The elimination of dendritic branches tended to increase the symmetry of the tree, as revealed by topological analysis. Later, between 13-15 days and 19-30 days, there was a reelaboration of the dendritic arborization returning to a configuration similar to that found in the newborn. The length of terminal branches was shorter at 19-30 days, while the length of preterminal branches did not change, suggesting that the proliferation of branches at 19-30 days takes place in the intermediate parts of terminal branches. The three-dimensional distribution of dendrites was analyzed by dividing space into six equal volumes (hexants). This analysis revealed that GG motoneurons have major components of their dendritic tree oriented in the lateral, medial, and dorsal hexants. Further two-dimensional polar analysis (consisting of eight sectors) revealed a reconfiguration of the tree from birth up to 5-6 days involving resorption of dendrites in the dorsal, dorsomedial, and medial sectors and growth in the lateral sector. Later in development (between 13-15 days and 19-30 days), there was growth in all sectors, but of a greater magnitude in the dorsomedial, medial, and dorsolateral sectors.

Distribution of synaptic terminals from prepositus neurones on the collicular maps

The distribution of synaptic terminals was quantified in the superior colliculus (SC) following injections of Phaseolus vulgaris-Leucoagglutinin in the ventral prepositus hypoglossi nucleus (PH) and adjacent reticular formation. Labelled axons distribute terminals within the intermediate and the deep layers on both sides. Within the former, their distribution reproduces the representation of the visual hemifield on the same side as the injected PH. Additionally the density of boutons gradually increases in the contralateral SC, from the projection of the area centralis towards the periphery, i.e. towards regions coding for larger saccades. Such a differential synaptic input may provide the neuronal basis for a temporal to spatial transformation of the feedback signal controlling gaze shifts. A theoretical model is proposed.

Bunina bodies in neurons of the medullary reticular formation in amyotrophic lateral sclerosis

To determine how often Bunina bodies (BBs) appear in the medullary reticular formation (MRF) in amyotrophic lateral sclerosis (ALS), we microscopically examined 20 serial sections of MRFs from each of nine autopsied ALS cases, which had BBs in the lower motor neurons, including those of cranial motor nuclei. In 1 of them, the pontine tegmentum was examined in the same way. In 8 cases one to several BB-containing neurons in the MRF were seen. The case in which the pontine tegmentum was also investigated exhibited several neurons with BBs in this region. Some of the BBs in the MRFs were confirmed by electron microscopy. Thus, this study demonstrates the common appearance of BBs, although the number is small, in the MRF, indicating that pathological processes that undermine the lower motor neurons in ALS in some way also affect neurons other than motor neurons in this condition.

The effect of axon injury on microtubule-associated proteins MAP2, 3 and 5 in the hypoglossal nucleus of the adult rat

Microtubule-associated proteins appear to be critical elements in the stabilization of microtubules during neurite development. Axon injury results in a new burst of axonal growth activity as well as in partial dendritic involution. With this background we have examined the immunocytochemical staining pattern for microtubule-associated proteins 2, 3 and 5 in the hypoglossal nucleus of adult rats following unilateral hypoglossal nerve resection. From four days to six weeks postlesion a significant reduction in microtubule-associated protein 2-like immunoreactivity was observed in the neuropil and neuronal perikarya of the hypoglossal nucleus ipsilateral to nerve transaction. Microtubule-associated protein 5-like immunoreactivity was reduced in neuronal perikarya and neuropil four days to two weeks after injury. After six weeks microtubule-associated protein 5-like immunoreactivity had returned to normal levels. Microtubule-associated protein 3-like immunoreactivity, which was observed in glial cell perikarya and axons, but not neuronal perikarya or dendrites, appeared to be essentially unaltered. The reduced levels of microtubule-associated proteins 2 and 5 may be factors contributing to previously documented axotomy-induced dendritic retraction. The decrease in microtubule-associated protein 5 staining and absence of microtubule-associated protein 3 expression in axotomized neurons contrast with the situation in developing neurons, and demonstrate that the neuronal reaction to axon injury in mature mammals involves a specific series of events distinct from the developmental process.

[Stereologic analysis of the human hypoglossal nucleus during the period ranging from the 22nd postovulatory week until birth]

The hypoglossal nucleus consists of the cells of the fourth stage of maturation according to Rakić. However, there are obvious differences and one of them is observable in the degree of staining intensivity of their Nissl bodies and nuclear inclusions. The stereological analysis revealed a constant decreasing of numerical density of the nerve cells nuclei in stages investigated. The decrease of the numerical density was highly significant (p < 0.001), probably due to the tissue growth and the total increase of nucleus i.e. its neuropi. The shrinkage of the tissue must be taken into consideration, too.

[The fine structure of the nucleus of the hypoglossal nerve of sheep and goats]

In the small domesticated ruminants the nucleus of the hypoglossal nerve is situated in close relationship to the median line in the middle of the elongated medulla. The nucleus is divided by the obex into a rostral and a caudal portion. In the sheep, four distinct subnuclei can be recognized, whereas in the dwarf goat great variations in the arrangement of cell groups exists. In both animals large and medium sized neurons are observed. The large neurons are characterized by densely packed small organelles. The medium sized neurons vary between a pale and an electron dense type. According to the size and morphology of the vesicles three types of synaptic contacts can be differentiated. Synapses of type 2 contain clear round and flattened vesicles and are partially accompanied by subsurface cisterns.

Topographically organized projections from the nucleus subceruleus to the hypoglossal nucleus in the rat: a light and electron microscopic study with complementary axonal transport techniques

Projections from the nucleus subceruleus (nSC) to the hypoglossal nucleus (XII) were investigated with complementary retrograde and anterograde axonal transport techniques at the light and electron microscopic level in the rat. Injections of WGA-HRP into XII resulted in labeling of neurons in and around the nSC. Labeled nSC neurons were few in number (less than 4 per 40-60 microns sections) and variable in size and shape. Most labeled nSC neurons were medium-sized (mean = 16.89 microns), fusiform, triangular, or oval, with 3-4 dendrites typically oriented dorsomedially and ventrolaterally. These neurons were found throughout the rostrocaudal extent of the nSC but were most numerous medial, dorsomedial, and ventromedial to the motor trigeminal nucleus. Others were observed rostral to the motor trigeminal nucleus and ventral to the parabrachial nuclear complex. Confirmation of retrograde results was obtained following injections of tritiated amino acids or WGA-HRP into the nSC. This resulted in labeling throughout the rostrocaudal extent of XII mainly ipsilaterally. Labeled fibers descended the brainstem in the dorsolateral and, to a lesser extent, in the ventromedial component of Probst's tract. Fibers entered XII mainly rostrally along the lateral border of the nucleus. All regions of XII were recipients of nSC afferents, but the caudoventromedial quadrant contained the greatest density of terminal labeling. Electron microscopic evaluation confirmed that nSC afferents synapsed on motoneurons in XII. Axon terminals containing WGA-HRP reaction product were found contacting dendrites and somata, but primarily the former (81.3% versus 10.6%). Axodendritic terminals synapsed mainly on medium-to-small sized dendrites (less than 3 microns in diameter). The majority of labeled axodendritic terminals (90.1%) contained small, round, and clear synaptic vesicles (S-type: 20-50 nm) and were associated with an asymmetric (60.6%), symmetric (11.4%), or no (18%) postsynaptic specialization. By contrast, most axosomatic terminals contained flattened vesicles (F-type) and formed a symmetric or no postsynaptic specialization (75%). Large dense core vesicles (55-90 nm) were observed within a small proportion of all labeled axon terminals (1.3%). The results from this study demonstrate that the nSC projects to XII, preferentially targets a specific subgrouping of protrusor motoneurons, and synapses on both somata and dendrites, although mainly on the latter. The implications of these data are discussed relative to tongue control.

Dendritic development of motor neurons in the cervical anterior horn and hypoglossal nucleus of normal infants and victims of sudden infant death syndrome

Morphometric Golgi methods were used to study dendritic development of neurons in the cervical ventral and dorsal horns and the hypoglossal nucleus of 8 victims of sudden infant death syndrome and 20 age-matched control infants. The dendrites and spines of these neurons proliferated rapidly until 28 weeks gestation, then increased slowly until shortly after birth. Dendritic spine density of motor neurons in the cervical anterior horn and hypoglossal nucleus of victims of sudden infant death syndrome was similar to that of the controls. Thus, the delayed maturation of dendritic spines seen in the reticular formation and vagal nuclei is not present in motor neurons of the cervical anterior horn and hypoglossal nucleus.

Serotonin-containing axon terminals in the hypoglossal nucleus of the rat. An immuno-electronmicroscopic study

The morphology and distribution of serotonin-containing axon terminals in the rat hypoglossal nucleus (XII) was investigated immunocytochemically at the electron microscopic level. Serotonin-positive profiles were found throughout all regions of XII and included unmyelinated axons, varicosities and axon terminals. Most labeled profiles (68.1%) were nonsynaptic unmyelinated axons and varicosities, while synaptic profiles, ending on dendrites and somata, were seen less frequently (28.7%). The majority of labeled axon terminals (76.9%) ended on small-to-medium-sized dendrites. Most axodendritic terminals contained small, round agranular vesicles (20-55 microns), several large (60-100 microns) dense core vesicles, and were associated with a pronounced asymmetric postsynaptic specialization. By contrast, labeled axosomatic terminals were seen less often than those ending on dendrites (23.0%). Axosomatic terminals typically contained small, round, agranular and large dense core vesicles and were associated with a symmetric or no postsynaptic specialization. These results provide the structural substrates for elucidating the functional role of serotonin in tongue control.

A morphometric analysis of the somata and organelles of regenerating hypoglossal motoneurons from the rat

A detailed morphometric evaluation of the somata and organelles of regenerating hypoglossal motoneurons from the rat was conducted. The volume of the hypoglossal nucleus and various parameters used to appraise neuronal size were estimated from 50 microns sections. The subcellular composition of randomly selected neurons was quantified from 1 micron and ultrathin sections. The volume of neuronal nuclei, nucleoli, mitochondria and lysosomes as well as the surface area of intracellular membranes were determined. Seven to 30 days following axotomy the volume of the hypoglossal nucleus was significantly diminished, undoubtedly reflecting dendritic retraction (P less than 0.05). Concomitantly, all estimates of neuronal size indicated significant neuronal enlargement (P less than 0.05). Ultrastructural alterations were most prominent 7 days following nerve transection: nucleolar volume was significantly increased, rough endoplasmic reticulum surface area was reduced, and non-Golgi smooth membrane surface area increased (P less than 0.05). In general, other organelles resisted the influence of axotomy and all ultrastructural parameters returned to control levels 21 to 30 days following the nerve transection. Functional recovery was detected in all animals 21 and 30 days following axotomy. The measured responses of axotomized hypoglossal motoneurons are similar to those reported for retinal ganglion cells of the goldfish (Whitnall & Grafstein, 1982, 1983), suggesting common metabolic events among these distinct neuronal populations following axonal transection.

Reticulo- and trigemino-hypoglossal connections: a quantitative comparison of ultrastructural substrates

Axon terminals were identified and characterized by electron microscopy after injections of horseradish peroxidase (HRP) into the spinal V nucleus (SPVN) or the medullary reticular formation adjacent to the XIIth nucleus. The synaptic organization and topology of these two different populations of hypoglossal afferents (T-XII and R-XII respectively) were determined by quantitative comparisons. Significant differences were obtained in the ratios of morphological types of terminals, sizes of axonal endings and their location on postsynaptic structures. Axon terminals containing spherical vesicles (S-terminals) and those with flattened/pleomorphic vesicles (F-terminals) were anterogradely labeled with HRP from both injection sites. However, the S/F ratio for R-XII terminals was 1.2:1 compared to 2.6:1 for T-XII afferents. Asymmetrical membrane densities (Gray Type I) were the predominant form of junctional specialization for S-terminal synapses. Asymmetrical densities with subjunctional dense bodies/bars (S-Taxi) were associated with a higher proportion of T-XII synapses than R-XII synapses. Almost all of the F-terminals from both sources had symmetrical densities (Gray Type II). The average diameter of R-XII terminals was greater than that of T-XII terminals. R-XII-F terminals were the largest terminals. The majority of axon terminals from both sources formed axodendritic synapses. However, R-XII terminals had a higher incidence (10% vs. 3%) of axosomatic contacts. The proportion of R-XII-F-terminals decreased from the central toward the distal dendrites, whereas the opposite was found for T-XII-F and T-XII-S-terminals. In contrast to these findings, R-XII-S-terminals were more uniformly distributed on dendrites of all sizes.(ABSTRACT TRUNCATED AT 250 WORDS)

The onset and rate of myelination in six peripheral and autonomic nerves of the rat

A light and electron microscopic study was carried out of the numbers of myelinated fibres in 6 nerves of the rat for 7 age groups from birth to 73 weeks. The hypoglossal nerve and the mandibular branch of the facial nerve had short and early myelination periods, essentially complete by the second week. The glossopharyngeal nerve and the sympathetic rami communicantes myelinated late and over a protracted period. Myelination of the rami communicantes continued up to 20 weeks, followed by a marked loss of fibres in the 73 week animals. Intercostal and saphenous nerves had intermediary patterns. There was evidence of subpopulations myelinating at different times. Measurements of myelin sheath thickness showed variations of relative sheath thickness with age, between nerves and for subpopulations of nerves. Late myelination corresponded to relatively thin myelin sheaths. Statistical two-stage-density cluster analysis by computer was used for analysing complex fibre populations. The developmental changes of three subpopulations of the intercostal nerve are documented. Nerves also differed in their rates of axon growth. The increment in axon calibre was small and late for sympathetic fibres. Intercostal and facial nerve fibres had rapid axon growth with different growth rates for subpopulations.

Morphological identification of an interneuron in the hypoglossal nucleus of the rat: a combined Golgi-electron microscopic study

Hypoglossal small neurons of adult and juvenile (10-15-day-old) rats were examined by a combined Golgi-electron microscopic technique. In adult rats, Golgi-impregnated neurons were fusiform or ovoid (17 X 12 micron) and emitted a few primary dendrites with few branches and few spines and an axon mainly from the proximal portion of the primary dendrite. At the ultrastructural level, the soma displayed an invaginated nucleus with a conspicuous nucleolus and a relatively scanty cytoplasm in which cisternae of rough endoplasmic reticulum were not organized into extensive lamellar arrays. A moderate number of axon terminals, which contained spherical clear or pleomorphic vesicles approximately 25-40 nm in diameter, formed symmetric or asymmetric synapses on the soma, the dendrites, the axon hillock, and the initial segment. In a preparation from the juvenile rat, we could trace a full axon trajectory of the small neuron. In this sample, in which a small neuron and a motoneuron were simultaneously impregnated, the axon of the small neuron was found to receive an axoaxonic symmetric synapse with pleomorphic vesicles on a varicosity and to contact the motoneuron dendrites by means of another varicosity of the main axon and of two boutons from an axon collateral. The varicosity and the boutons contained pleomorphic synaptic vesicles and synapsed symmetrically with the motoneuron dendrites. We identified the small neuron in the rat hypoglossal nucleus morphologicaly as a Golgi type II interneuron. We discuss its function in relation to the GABAergic nature of small neurons (Takasu et al.: J. Comp. Neurol. 263:42-53, '87).

Effect on the rat hypoglossal nucleus of vinblastine and colchicine applied to the intact or transected hypoglossal nerve

The possibility that interruption of axonal transport in otherwise intact axons induces retrograde neuronal and nonneuronal reactions was examined. In addition, the proposal that blockade of axonal transport proximal to nerve injury might inhibit or delay the axon reaction was examined. Cuffs containing various doses of vinblastine were applied to the intact hypoglossal nerve. Colchicine was applied in a similar way to the intact hypoglossal nerve, injected directly into the intact nerve, or administered proximal to the site of hypoglossal nerve transection. The effect on retrograde axonal transport in the nerve was evaluated in the vinblastine experiments by the retrograde horseradish peroxidase (HRP) technique following injection of HRP or wheat germ agglutinin-conjugated HRP into the tongue. A dose of 0.01% caused an almost complete, but transient, blockade of the retrograde transport of the tracer, and induced a clearcut chromatolytic reaction in hypoglossal neurons. The chromatolytic changes were accompanied by a significant increase in the number of glial cells, many of which were identified as microglia. Similar results were obtained with colchicine alone or in combination with nerve transection. Signs of Wallerian degeneration after vinblastine treatment (0.01%) were observed only in a small number of myelinated fibers. The findings are compatible with the view that depletion of retrogradely transported factors from the peripheral innervation territory (including the distal nerve stump) to the perikaryon and/or a premature return of anterogradely transported substances at the site of drug exposure are factors inducing retrograde neuronal and nonneuronal changes.

The ultrastructural morphology and distribution of trigemino-hypoglossal connections labeled with horseradish peroxidase

Axon terminals projecting to the hypoglossal nucleus have been identified and characterized by electron microscopy following injections of horseradish peroxidase (HRP) into pars interpolaris of the spinal trigeminal nucleus (SPVN) in adult rats. Over 70% of the anterogradely labeled terminals contained spherical vesicles (S-terminals) and their synaptic densities were chiefly asymmetrical (Gray Type I). The rest (28%) of the labeled terminals had flattened vesicles (F-terminals) and predominantly established symmetrical (Gray Type II) synaptic contacts. The diameters of labeled terminals were 0.5-2.5 micron. Two-thirds of the S-terminals had diameters less than 1.25 micron, whereas, F-terminals were distributed equally in the higher (greater than 1.25) and lower (less than 1.25) diameter ranges. Most axon terminals ended on dendrites of hypoglossal neurons; some, chiefly F-terminals, formed axosomatic endings. Dendrites had diameters of 0.5-5 micron. The majority of S- and F-terminals ended on dendrites with diameters of less than 2.5 micron. However, more F-terminals (17%) than S-terminals (11%) were presynaptic to dendrites greater than 2.5 micron in diameter. Experiments in which anterograde HRP labeling of trigemino-hypoglossal projections was combined with retrograde WGA-HRP labeling of motoneurons projecting to the tongue, demonstrated that SPVN axons end on dendrites of these motoneurons. Whether some of the trigeminal fibers also terminate on intrinsic hypoglossal interneurons remains to be determined.

Direct contacts between glossopharyngeal afferent terminals and hypoglossal motoneurons revealed by double labeling with cobaltic-lysine and horseradish peroxidase in the Japanese toad

Glossopharyngeal (IX) afferents and hypoglossal (XII) motoneurons of the Japanese toad were simultaneously labeled with cobaltic-lysine and horseradish peroxidase, respectively. Some of the terminal branches of the IX afferents had direct contacts with the dorsal dendrites, the lateral dendrites and the somata of the XII motoneurons, but not with the medial dendrites. Such direct contacts mainly occurred in the rostral region of the dorsomedial XII nucleus, where tongue-retractor motoneurons predominate, but not in the caudal region nor in the ventrolateral XII nucleus.

Immunocytochemical localization of gamma-aminobutyric acid in the hypoglossal nucleus of the macaque monkey, Macaca fuscata: a light and electron microscopic study

The hypoglossal nucleus of the macaque monkey Macaca fuscata was investigated with light and electron microscopic immunocytochemistry with an antibody directed against gamma-aminobutyric acid (GABA). At the light microscopic level, GABA immunoreactivity was present in small neurons, punctate structures, and thin, fiberlike structures. These GABA-positive elements were distributed throughout the hypoglossal nucleus at rostrocaudal levels. There was no immunoreactivity in the hypoglossal motoneurons. The GABA-positive small neurons were fusiform or ovoid (15 X 9 micron) and extended a few proximal dendrites from both poles. At the ultrastructural level, these small neurons were characterized by a markedly invaginated nucleus and a scanty cytoplasm in which cisternae of rough endoplasmic reticulum were not organized into extensive lamellar arrays as seen in the motorneurons. The GABA-positive punctate structures at the light microscopic level were identified as vesicle-containing axon boutons at the electron microscopic level. These GABA-positive axon terminals made synaptic contacts mainly with the dendrites of the motoneurons and infrequently with the somata. The majority of them made symmetric synapses and they contained pleomorphic synaptic vesicles. However, a small number of GABA-positive terminals (7%) formed asymmetric synapses with the dendrites of motoneurons, and these contacts exhibited postsynaptic dense bars or Taxi bodies lying beneath the postsynaptic membranes. There were no GABA-positive boutons that contacted the cell bodies of the small neurons. Although GABA-positive myelinated and unmyelinated axons were seen as thin, fiberlike structures, these myelinated and unmyelinated axons rarely gave rise to boutons on the motoneurons. The present study suggests that GABAergic inhibition in the monkey hypoglossal nucleus occurs mainly on the dendrites of the motoneurons and to some extent on the somata.

An improved method for correlative light and electron microscopic examination of cobaltic-lysine-labelled neurons

We describe an improved method for correlative light and electron microscopic examination of synaptic organization of neurons extracellularly labelled by the axonal transport of cobaltic-lysine (Co-lys). After filling the neurons with Co-lys and precipitating the CoS, the brain is fixed in a double-aldehyde fixative, and thick slices are cut using a Microslicer. The slices are intensified using a physical developer, postfixed in OsO4 and embedded in resin. By cutting alternating semithin and ultrathin sections, it is possible to specify sites and types of synaptic contacts on labelled neuronal profiles.

Cytology and intrinsic organization of the perihypoglossal nuclei in the cat

The morphology of the neurons in the perihypoglossal nuclei (nucleus prepositus, nucleus intercalatus, and nucleus of Roller) of the cat was studied in normal Nissl material, and by intracellular injection of horseradish peroxidase. The neurons in the nucleus prepositus were morphologically heterogeneous. Many of the cells in the ventromedial part of the caudal prepositus had relatively large somata, and complex dendritic trees which arose from numerous proximal dendrites and ramified extensively in the ventromedial aspect of the prepositus. These neurons had thick axons which typically did not give rise to local collaterals. The cells in the dorsolateral part of the caudal prepositus tended to have small somata, and dendritic trees which arborized in that region of the nucleus. The axons of these small cells frequently gave rise to local collaterals which terminated in the prepositus. Most of the cells in the prepositus had medium-sized somata and relatively few dendrites which branched in an isodendritic manner and extended for long distances, frequently leaving the nucleus. These "principal" prepositus neurons had axons which arborized unilaterally, and often gave rise to collaterals which terminated in either the ipsilateral or contralateral prepositus. The neurons in the nucleus of Roller and nucleus intercalatus which were intracellularly injected with horseradish peroxidase resembled the multidendritic and small prepositus cells, respectively. The intrinsic connectivity of the perihypoglossal nuclei was also studied by injecting horseradish peroxidase or 3H-leucine into the prepositus nucleus. The results of these experiments suggest that the perihypoglossal nuclei are highly interconnected bilaterally, although the large cells in the ventromedial prepositus and the nucleus of Roller contribute little to these intrinsic connections, and are not major recipients of intrinsic inputs. On the other hand, the magnitude of the reciprocal connections between the prepositus and the nucleus intercalatus suggests that they are functionally related.

The ultrastructural identification of reticulo-hypoglossal axon terminals anterogradely labeled with horseradish peroxidase

Injections of horseradish peroxidase (HRP) or wheat-germ agglutinin-horseradish peroxidase (WGA-HRP) into the nucleus reticularis parvocellularis (RPc) produced anterograde labeling of axon terminals within the hypoglossal nucleus. Based on morphological parameters of vesicle population, membrane specializations, and postsynaptic articulations, two types of axon terminals derived from neurons in RPc end on hypoglossal neurons. More than half of the terminals contained spherical vesicles (S-type), established asymmetrical membrane specializations and contacted proximal and medium-sized dendrites. The remaining labeled terminals had flattened vesicles (F-type), symmetrical membrane densities and apposed medium and small dendrites. The morphological differences expressed in the two types of terminals may reflect physiological and/or pharmacological differences in the action of RPc neurons on motoneurons in the hypoglossal nucleus.

The glial reaction in the course of axon regeneration: a stereological study of the rat hypoglossal nucleus

Both hypoglossal nuclei were examined by electron microscope stereology after unilateral axotomy. The principal aim of this study was a quantitative assessment of the accompanying glial reaction. Volume densities (%) of neuronal and glial perikarya, as well as their processes, were evaluated in terms of volume plus surface densities (mm-1). In addition, specific surfaces (surface to volume ratio) of these neuronal and glial processes were assessed. First, a temporary decrease of dendritic volume density was detected on the ipsilateral side only. Further, the astrocytic reaction displayed differences between stem and lamellar processes. One day after axotomy, a bilateral decrease of volume density, as well as surface density of stem processes, was observed, yet their normal dimensions soon were reestablished. However, a more severe lamellar process reaction was evident. During the first 4 days, a significant increase of volume density and surface density was apparent. In the contralateral hypoglossal nucleus, this glial reaction also occurred but disappeared by day 14, whereas the ipsilateral nucleus continued to display a severe reaction of lamellar processes, only returning to normal status at day 77. In addition, a transient, severe reaction of presumptive microglia was established by employing the volume density and surface density quantitation procedure. Nevertheless, in comparison with the volume and surface contribution of astrocytic processes, the presumed microglial component was minimal. This study indicates a two-step involvement of astrocytes in regenerative repair. Namely, the first phase seems to result in an increase of lamellar processes through reshaping of the stem process.(ABSTRACT TRUNCATED AT 250 WORDS)

Aluminum effect on slow axonal transport: a novel impairment of neurofilament transport

Administration of aluminum (Al) produces accumulation of neurofilaments (NF), called neurofibrillary tangles (NFT), in neuronal cell bodies and proximal axonal segments. This study was undertaken to investigate whether these changes are associated with impairment of the slow axonal transport. Local administration of AlCl3 induced the formation of NFT in 90 to 100% of the rabbit hypoglossal neurons. [35S]Methionine was then administered to the hypoglossal nerve nuclei. The hypoglossal nerves were processed 18 or 28 days later for one- and two-dimensional SDS-polyacrylamide gel electrophoresis and fluorography. Labeled NF polypeptides and a polypeptide of 57 kilodaltons (Kd) were not detectable beyond the proximal 9-mm segment of the hypoglossal nerve in Al-treated rabbits 18 days after labeling, whereas they were present up to 27 mm from the medulla in controls. Tubulin and polypeptides migrating with slow component b were not significantly affected. In rabbits sacrificed 28 days after labeling, accumulation of NF subunits within the proximal 9 mm of hypoglossal nerve was less dramatic, and labeled NF were present up to 30 mm from the medulla whereas they were detectable up to 45 mm in controls. Morphological studies demonstrated the presence of enlarged axons filled with NF in the proximal 9 mm of the hypoglossal nerve. In nerve segments immediately distal, axons were markedly reduced in size and contained no NF but an apparently normal number of microtubules and other organelles. Transport of NF and of a 57-Kd polypeptide is markedly but reversibly slowed down or blocked within the proximal 9-mm segments of the hypoglossal nerve following Al administration to the hypoglossal nucleus. It is suggested that NF transport is maintained distally, resulting in lack of NF in axonal segments immediately distal to the block. Local Al intoxication provides a novel model of impairment of NF transport.

The ultrastructure of two distinct neuron populations in the hypoglossal nucleus of the rat

An ultrastructural study of the hypoglossal nucleus (XII) in the rat has revealed two distinct neuronal populations. Hypoglossal motoneurons comprised the largest population of neurons in XII and were identified following injection of horseradish (HRP) into the tongue. Motoneurons were large (25-50 mu), multipolar in shape and distributed throughout XII. The nucleus was large, round and centrally located, and the cytoplasm was characterized by dense lamellar arrays of rough endoplasmic reticulum. In contrast, a second population of small (10-18 mu), round to oval shaped neurons was found restricted to the ventral and dorsolateral regions of XII. The nucleus was markedly invaginated and eccentric, the cytoplasm scant and filled with free ribosomes, and the absence of lamellar arrays of rough endoplasmic reticulum was conspicuous. Neurons of this type were never found to contain HRP reaction product. These results demonstrate that the hypoglossal nucleus does not consist solely of motoneurons, but includes a distinctly separate, presumably non-motoneuronal pool. Arguments are presented in favor of this second neuron population being interneurons. The functional significance of these findings in relation to tongue control is discussed.