Motoneuron Somata Research Articles

Roles of glutamate and FMRFamide-related peptides at the chromatophore neuromuscular junction in the cuttlefish, Sepia officinalis.

Body patterning behavior, the expression of highly intricate patterns, is ubiquitous among all unshelled cephalopods. These body patterns are in part generated by the coordinated activity of millions of skin chromatophore organs, each of which is regulated by a set of chromatophore muscles directly innervated by centrally located chromatophore motoneurons. This study addresses the question of the identity and function of the transmitter(s) at the chromatophore neuromuscular junction (NMJ) in the European cuttlefish Sepia officinalis. Glutamate application causes a rapid contraction of the chromatophore muscles, resulting in chromatophore expansion. Pharmacological studies demonstrate that the chromatophore muscles contain receptors blocked by glutamate-specific antagonists. Glutamate-like immunoreactivity is also present in the somata of putative chromatophore motoneurons. These findings suggest that glutamate likely acts as a neurotransmitter at the chromatophore NMJ. Evidence is also presented suggesting that FMRFamide-related peptides (FaRPs) also function as neurotransmitters at the Sepia chromatophore NMJ. FMRFamide application causes contraction of chromatophore muscles; however, the FMRFamide effect is slower and longer lasting than that of glutamate. Pharmacological data show that FMRFamide acts directly on the chromatophore muscles. FMRFamide-immunopositive cells are present in the posterior chromatophore lobe, the putative location of the chromatophore motoneuron somata. A combination of immunocytochemistry and in situ hybridization shows that some putative chromatophore motoneurons express FaRP-like immunoreactivity and an FaRP-coding mRNA transcript. Many FMRFamide-immunopositive cells in the posterior chromatophore lobes also express glutamate-like immunoreactivity. We conclude that glutamate and FaRPs likely function as fast and slow transmitters, respectively, at the Sepia chromatophore NMJ.

Changes in expression of NMDA receptor subunits in the rat lumbar spinal cord following neonatal nerve injury.

The vulnerability of motoneurones to glutamate has been implicated in neurological disorders such as amyotrophic lateral sclerosis but it is not known whether specific receptor subtypes mediate this effect. In order to investigate this further, the expression of N-methyl-D-aspartate (NMDA) receptor subunits was studied during the first three post-natal weeks when motoneurones are differentially vulnerable to injury following neonatal nerve crush compared to the adult. Unilateral nerve crush was carried out at day 2 after birth (P2) which causes a decrease of 66% in motoneurone number by 14 days (P14). To study receptor expression in identified motoneurones, serial section analysis was carried out on retrogradely labelled common peroneal (CP) motoneurones by combined immunocytochemistry and in situ hybridization (ISH). mRNA levels were also quantified in homogenates from lumbar spinal cords in which the side ipsilateral to the crush was separated from the contralateral side. The NR1 subunit of the NMDA receptor was widely distributed in the spinal cord being expressed most strongly in motoneurone somata particularly during the neonatal period (P3-P7). The NR2 subunits were also expressed at higher levels in the somata and dendrites of neonatal motoneurones compared to older animals. NR2B mRNA was expressed at low to moderate levels throughout the studied period whereas NR2A mRNA levels were low until P21. Following unilateral nerve crush, an initial decrease in NR1 mRNA occurred at one day after nerve crush (P3) in labelled CP motoneurones ipsilateral to the crush which was followed by a significant increase in NR1 subunit expression at 5 days post-injury. This increase was bilateral although reaching greater significance ipsilateral to the crush compared with sham-operated animals. A significant increase in NR1 and NR2B mRNA post injury was also detected in spinal cord homogenates. In addition, the changes in levels of NR1 and NR2B mRNA were reflected by comparable bilateral changes at P7 in receptor protein determined by quantitative immunocytochemical analysis of NR1 and NR2 subunit expression in identified CP motoneurones indicating a co-ordinated regulation of receptor subunits in response to injury.

Arborization of dewlap motoneurons in the green anole lizard ( Anolis carolinensis) is not sexually dimorphic

Male anoles extend a bright red throat fan, called a dewlap, during both courtship and aggressive encounters. Female anoles perform this behavior less often than males and only in aggression towards both sexes. The cartilage, muscle fibers, and motoneuron somata controlling the display are larger in males than females. In the present study, we used the Golgi technique in an effort to characterize more completely the morphology of these dewlap motoneurons, and to investigate whether the dendritic arborization is different between the sexes. In addition to describing the morphology, we report that the length of processes, and numbers of primary processes and branch points are comparable in males and females. This similarity in arborization represents an intriguing contrast to other sexually dimorphic neuromuscular systems.

Localization of GABA- and glutamate-like immunoreactivity in the cardiac ganglion of the lobster Panulirus argus.

Wholemount immunohistochemical methods were used to examine the localization of gamma-aminobutyric acid (GABA) and glutamate within the cardiac system of the Caribbean spiny lobster Panulirus argus. All of the GABA-like immunoreactivity (GABAi) in the cardiac ganglion originated from a single bilateral pair of fibers that entered the heart via the two dorsal nerves. Each GABAi axon bifurcated upon entering the ganglion and gave rise to varicose fibers that surrounded the somata and initial segments of the five large motor neurons. The four small posterior cells did not appear to receive somatic contacts. Double-labeling experiments in which individual motor neurons were injected with Neurobiotin showed that their dendritic processes, which project to muscle bundles adjacent to the ganglion and are thought to respond to stretch, were also accompanied by branches of the GABAi fibers. Glutamate-like immunoreactivity (GLUi) was present in each of the motor neuron cell bodies. In some preparations, GLUi was also detected in large caliber fibers in the major ganglionic nerves. These fibers gave rise to more slender branches that innervated the cardiac muscle bundles. GLUi was also found in the small cell bodies and in fibers surrounding motor neuron somata. Taken together, these findings support previous electrophysiological, pharmacological and anatomical studies indicating that GABA mediates extrinsic inhibition and that glutamate acts as a neuromuscular and intraganglionic transmitter in this system. While axosomatic contacts may play a major role in both transmitter systems, the GABAergic inhibition also appears to involve substantial axodendritic synaptic signaling.

Development, neurochemical properties, and axonal projections of a population of last-order premotor interneurons in the white matter of the chick lumbosacral spinal cord.

There is general agreement that last-order premotor interneurons-a set of neurons that integrate activities generated by the spinal motor apparatus, sensory information and volleys arising from higher motor centres, and transmit the integrated signals to motoneurons through monosynaptic contacts-play crucial roles in the initiation and maintenance of spinal motor activities. Here, we demonstrate the development, neurochemical properties, and axonal projections of a unique group of last-order premotor interneurons within the ventrolateral aspect of the lateral funiculus of the chick lumbosacral spinal cord. Neurons expressing immunoreactivity for neuron-specific enolase were first detected in the ventrolateral white matter at embryonic day 9 (E9). The numbers of immunoreactive neurons were significantly increased at E10-E12, while most of them were gradually concentrated in small segmentally arranged nuclei (referred to as major nuclei of Hofmann) protruding from the white matter in a necklace like fashion dorsal to the ventral roots. The major nuclei of Hofmann became more prominent at E12-E16, but substantial numbers of cells were still located within the ventrolateral white matter (referred to as minor nucleus of Hofmann). The distribution of immunoreactive neurons achieved by E16 was maintained during later developmental stages and was also characteristic of adult animals. After injection of Phaseolus vulgaris-leucoagglutinin unilaterally into the minor nucleus of Hofmann, labeled fibres were detected in the ventrolateral white matter ipsilateral to the injection site. Ascending and descending fibres were revealed throughout the entire rostro-caudal length of the lumbosacral spinal cord. Axon terminals were predominantly found within the lateral motor column and the ventral regions of lamina VII ipsilateral to the injection site. Several axon varicosities made close appositions with somata and dendrites of motoneurons, which were identified as synaptic contacts in a consecutive electron microscopic study. With the postembedding immunogold method, 21 of 97 labeled terminals investigated were immunoreactive for glycine and 2 of them showed immunoreactivity for gamma-aminobutyric acid (GABA). The axon trajectories of neurons within the minor nucleus of Hofmann suggest that some of these cells might represent a population of last-order premotor interneurons. J. Exp. Zool. 286:157-172, 2000.

Thoracic and prothoracic leg neuromuscular system of the praying mantid,Sphodromantis lineola (burmeister)

Historically, praying mantids have attracted attention because of their dramatic prey capture behavior, loosely termed the strike. However, little is known about the neuromuscular organization that underpins the behavior. Although once thought to be quite stereotyped, recent data indicate that the strike is quite plastic and can be aimed accurately within a relatively large three-dimensional space. Hence, successful prey capture requires the integration of (1) visual information, indicating prey has been recognized; and (2) proprioceptive information, indicating head and prothorax (i.e., visual field) position and initial leg positions. This study was undertaken as part of a larger program examining how such sensory information is integrated with the appropriate motor systems. Our goals were (1) to describe the gross thoracic and foreleg neuromuscular system of Sphodromantis lineola and (2) to identify the soma locations of the motor neurons associated with the largest leg nerve, N4, which travels the length of each leg. We found that the thoracic and foreleg neuromusculature of S. lineola are similar but not identical to what is known about just three other species of mantid, and that motor neuron somata associated with N4 are arranged in stereotypical, bilaterally symmetrical groups as they are in other orthopteroids, suggesting that this is a general organizational feature of the insect CNS.

Presence of the vesicular inhibitory amino acid transporter in GABAergic and glycinergic synaptic terminal boutons.

The characterization of the Caenorhabditis elegans unc-47 gene recently allowed the identification of a mammalian (gamma)-amino butyric acid (GABA) transporter, presumed to be located in the synaptic vesicle membrane. In situ hybridization data in rat brain suggested that it might also take up glycine and thus represent a general Vesicular Inhibitory Amino Acid Transporter (VIAAT). In the present study, we have investigated the localization of VIAAT in neurons by using a polyclonal antibody raised against the hydrophilic N-terminal domain of the protein. Light microscopy and immunocytochemistry in primary cultures or tissue sections of the rat spinal cord revealed that VIAAT was localized in a subset (63-65%) of synaptophysin-immunoreactive terminal boutons; among the VIAAT-positive terminals around motoneuronal somata, 32.9% of them were also immunoreactive for GAD65, a marker of GABAergic presynaptic endings. Labelling was also found apposed to clusters positive for the glycine receptor or for its associated protein gephyrin. At the ultrastructural level, VIAAT immunoreactivity was restricted to presynaptic boutons exhibiting classical inhibitory features and, within the boutons, concentrated over synaptic vesicle clusters. Pre-embedding detection of VIAAT followed by post-embedding detection of GABA or glycine on serial sections of the spinal cord or cerebellar cortex indicated that VIAAT was present in glycine-, GABA- or GABA- and glycine-containing boutons. Taken together, these data further support the view of a common vesicular transporter for these two inhibitory transmitters, which would be responsible for their costorage in the same synaptic vesicle and subsequent corelease at mixed GABA-and-glycine synapses.

Ionotropic glutamate receptor subunit distribution on hypoglossal motoneuronal pools in the rat.

The expression of ionotropic glutamate receptor subunits in the motoneuronal pools of the hypoglossal nucleus was studied using specific antibodies against subunits of the alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA), kainate and N-methyl-D-aspartate (NMDA) subtypes. The highest numbers of intensely immunolabelled motoneurons were found in the dorsal tier and caudoventromedial part of the hypoglossal nucleus with all antibodies except that against the GluR1 AMPA subunit. Labelling for the GluR1 subunit was weak except for caudally located groups of motoneurons which innervate tongue muscles related to respiratory activity. By contrast, most motoneurons were intensely immunostained with antibodies against GluR2/3 and GluR4 subunits of the AMPA subtype. The low staining observed using an antibody specific for the GluR2 subunit (which prevents Ca(2+)-entry through AMPA channels) strongly suggests that AMPA receptors in hypoglossal motoneurons are Ca(2+)-permeable. Immunolabelling for the GluR5/6/7 kainate receptor subunits was found in many motoneuronal somata as well as in thin axon-like profiles and puncta that resembled synaptic boutons. Most motoneurons were intensely immunostained for the NMDA receptor subunit NR1. These results show that the hypoglossal nucleus contains five heterogeneous pools of motoneurons which innervate functionally defined groups of tongue muscles. The uneven expression of the different receptor subunits analysed here could reflect diverse phenotypic properties of hypoglossal motoneurons which might be expected to generate different patterns of motor responses under different physiological or pathological conditions.

Effects of botulinum neurotoxin type A on the expression of gephyrin in cat abducens motoneurons

In this study, we investigated the effects of long-term synaptic blockade on postsynaptic receptor clustering at central inhibitory glycinergic synapses. High doses of botulinum neurotoxin type A injected in the lateral rectus muscle completely abolishes inhibitory postsynaptic potentials onto abducens motoneurons within 2 days postinjection, and transmission remains blocked for at least 2 months. Using this model, we analyzed the expression of gephyrin, a glycine receptor clustering protein, on the membrane of motoneuron somata after botulinum neurotoxin type A injection in their target muscle. Immunofluorescence or electron microscopy immunohistochemistry revealed gephyrin-immunoreactive clusters (most < 0.5 microm in diameter) densely covering the surface of control abducens motoneurons. Ultrastructurally, presynaptic terminals containing flattened synaptic vesicles (F terminals) were found associated with multiple gephyrin-immunoreactive postsynaptic densities (average 1.24 gephyrin clusters/F+ profile). No significant changes in gephyrin-immunoreactive clusters were observed at 5 days postinjection, but we found significant reductions (25-40%) in the density of gephyrin clusters 19 and 35 days postinjection. Hence, the physiological alterations reported in this model precede structural changes on postsynaptic receptor cluster density. The decrease in gephyrin-immunoreactive clusters was paralleled by reductions in synaptic covering (F+ terminals per 100 microm of membrane). Presumed inactive F+ terminals that remained attached to the motoneuron surface displayed normal gephyrin-immunoreactive clusters; however, the pre- and postsynaptic membranes in between synaptic active zones frequently appeared separated by enlarged extracellular spaces. We concluded that postsynaptic receptor cluster dissolution seemed more directly related to terminal retraction than to inactivity alone.

Decreased axosomatic input to motoneurons and astrogliosis in the spinal cord of aged rats.

An increasing body of evidence indicates that aging-related impairments of nervous functions are caused by damage to neuron integrity rather than by loss of neurons. By using electron microscopy, we have examined axosomatic boutons on spinal cord motoneurons derived from aged and young adult Sprague-Dawley rats. The main finding was that about half of the examined motoneuron somata from aged rats had a reduced (50%) bouton coverage, which seemed to be caused by a smaller number of axosomatic bouton profiles. Long stretches of the cell body plasma membrane were apposed by pale processes, and immunolabeling for glial fibrillary acidic protein (GFAP) disclosed that a number of the aged motoneurons appeared embedded in GFAP immunopositive processes. Lumbar motoneurons seemed to be more severely affected than cervical motoneurons. At the ultrastructural level, affected motoneurons disclosed plasma membrane irregularities with appendages/sprout-like extensions that in some cases were sites for axosomatic contacts.

Innervation pattern of a pool of nine excitatory motor neurons in the flexor tibiae muscle of a locust hind leg

The flexor tibiae muscle of a locust hind leg consists of 10-11 pairs of fibre bundles in the main body of the muscle and a distal pair of bundles that form the accessory flexor muscle, all of which insert onto a common tendon. It is much smaller than the antagonistic extensor tibiae muscle and yet it is innervated by nine excitatory motor neurons, compared with only two for the extensor. To determine the pattern of innervation within the muscle by individual motor neurons, branches of the nerve (N5B2) that supplies the different muscle bundles were backfilled to reveal somata in the metathoracic ganglion. This showed that different muscle bundles are innervated by different numbers of excitatory motor neurons. Physiological mapping of the innervation was then carried out by intracellular recordings from the somata of flexor motor neurons in the metathoracic ganglion using microelectrodes. Spikes were evoked in these neurons by the injection of current, and matching junctional potentials were sought in fibres throughout the muscle using a second intracellular electrode. Each motor neuron innervates only a restricted array of muscle fibres and, although some innervate a larger array than others, none innervates fibres throughout the muscle. Some motor neurons innervate only proximal fibres and others only more distal fibres, so that the most proximal and most distal bundles of muscle fibres are innervated by non-overlapping sets of motor neurons. More motor neurons innervate proximal bundles than distal ones, and there are some asymmetries in the number of motor neurons innervating corresponding bundles on either side of the tendon. Individual motor neurons cause slow, fast or intermediate movements of the tibia, but their patterns of innervation overlap in the different muscle bundles. Furthermore, individual muscle fibres may also be innervated by motor neurons with different properties.

Short day lengths delay development of the SNB neuromuscular system in the Siberian hamster, Phodopus sungorus

The Siberian hamster, Phodopus sungorus, breeds seasonally. In the laboratory, the seasonal breeding can be controlled by photoperiod, which affects the durations of nightly melatonin secretions. Winterlike short day lengths induce gonadal regression in adult animals, and pups born and maintained in short days undergo gonadal development much later than animals born into long days. The spinal nucleus of the bulbocavernosus (SNB) and its target muscles, the bulbocavernosus (BC) and levator ani (LA), comprise a sexually dimorphic, androgen-sensitive neuromuscular system involved in male reproduction. The SNB neuromuscular system was studied in male Siberian hamsters maintained from conception in short-day (8:16 h light/dark cycle) versus long-day (16:8 h light/dark cycle) conditions. At 40–47 days of age, development of three components of the SNB neuromuscular system were all significantly delayed in hamsters raised in the short photoperiod: BC/LA muscle weight, the size of SNB motoneuronal somata, and the area of the neuromuscular junctions at the BC/LA muscles of short-day hamsters were each significantly reduced relative to those of long-day counterparts. Thus, development of the SNB reproductive system is delayed under short day lengths in this species. © 1998 John Wiley & Sons, Inc. J Neurobiol 35: 355–360, 1998

Short day lengths delay development of the SNB neuromuscular system in the Siberian hamster,Phodopus sungorus

The Siberian hamster, Phodopus sungorus, breeds seasonally. In the laboratory, the seasonal breeding can be controlled by photoperiod, which affects the durations of nightly melatonin secretions. Winterlike short day lengths induce gonadal regression in adult animals, and pups born and maintained in short days undergo gonadal development much later than animals born into long days. The spinal nucleus of the bulbocavernosus (SNB) and its target muscles, the bulbocavernosus (BC) and levator ani (LA), comprise a sexually dimorphic, androgensensitive neuromuscular system involved in male reproduction. The SNB neuromuscular system was studied in male Siberian hamsters maintained from conception in short-day (8:16 h light/dark cycle) versus long-day (16:8 h light/dark cycle) conditions. At 40-47 days of age, development of three components of the SNB neuromuscular system were all significantly delayed in hamsters raised in the short photoperiod: BC/LA muscle weight, the size of SNB motoneuronal somata, and the area of the neuromuscular junctions at the BC/LA muscles of short-day hamsters were each significantly reduced relative to those of longday counterparts. Thus, development of the SNB reproductive system is delayed under short day lengths in this species.

Effects of long-term physical exercise on age-related changes of spinal motoneurons and peripheral nerves in rats

We examined the number and size of motoneurons and myelinated nerve fibers innervating the medial gastrocnemius (MG) muscle in the hindlimb of rats that were subjected to swimming for 10 months (30 min, 3 days/week) from 17 to 27 months of age. The number of MG motoneurons in exercised aged rats was slightly, but not significantly, greater than that in sedentary aged rats, and the number for both aged groups was significantly less compared to that in middle-aged (17-month-old) rats. The size of motoneuronal somata in the exercised aged rats was significantly larger than that in sedentary aged rats. Morphological parameters (fascicular area, fiber density, and axonal diameter) for the MG nerve in the exercised rats showed intermediate values between those for middle-aged and sedentary aged rats, although all of the differences in the means between groups were not significant. Thus, the overall changes seen in the exercised rats seem less compared to the changes in the sedentary rats, suggesting that long-term moderate exercise retards the progressive changes in motoneurons and peripheral nerves that develop in old age.

Changes in the synaptology of spinal motoneurons in zebrafish following spinal cord transection

Effects of spinal cord transection on the synaptology of zebrafish spinal motoneurons were studied. The transection was made at the level of the 14th vertebra and the synaptology of motoneuron somata and dendrites was analysed at the level of the 21st to the 23rd vertebrae at one month and three months after transection. Horseradish peroxidase, applied to the myotomal muscle, was used to label motoneuron somata and dendritic branches in central and in lateral areas of the neuropil (referred to as central and lateral dendritic profiles). Boutons impinging on motoneurons were classified according to the morphology of the vesicles. We discerned R-boutons with spherical vesicles, F-boutons with flat vesicles and DC-boutons with at least one dense core vesicle. The apposition lengths of R-, F- and DC-boutons and the circumference of labelled profiles were determined to assess the proportional covering of boutons on somata and dendrites. Ratio's of covering with R- and F-boutons (R/F ratio) for somata, central and lateral dendritic profiles were 1.1, 2.1, and 2.1 in control fish and 0.5, 0.5 and 0.9 in lesioned fish at one month after transection, respectively. The total covering of motoneurons in lesioned fish was decreased by 20% on somata and by 30% on lateral dendritic profiles, whereas central dendritic profiles did not change significantly. At three months after transection the R/F ratio's for somata, central and lateral dendritic profiles were 0.5, 0.7 and 0.6, respectively. The total covering on somata and central and lateral dendritic profiles was at control levels. The anatomical aspects of the changes in synaptology indicate that in control fish 50 to 60% of the R-boutons on the motoneuron surface originate from descending axons. In contrast, almost all F-boutons seem to be from local origin.

Androgen Mitigates Axotomy-Induced Decreases in Calbindin Expression in Motor Neurons

Androgens can rescue axotomized motor neurons from cell death. Here we examine a possible mechanism for this trophic action in juvenile Xenopus laevis: regulation of a calcium-binding protein, calbindin, after axotomy. Western analysis revealed that a monoclonal antibody to calbindin D specifically recognizes a single approximately 28 kDa band in X. laevis CNS and rat cerebellum. Retrograde transport of peroxidase combined with immunohistochemistry demonstrated that somata, axons, and synaptic terminals of laryngeal motor neurons in nucleus (N.) IX-X of X. laevis are calbindin-positive. The number of calbindin-positive cells was compared in the intact and axotomized sides of N.IX-X of gonadectomized males that were either hormonally untreated or DHT-treated for 1 month. Although axotomy decreased the number of calbindin-positive cells by 86% in hormonally untreated males, the decrease was only 56% in DHT-treated animals. Compared with hormonally untreated animals, the number of calbindin-labeled cells in N.IX-X of DHT-treated males was increased in both the intact (14%) and axotomized sides (75%). We conclude that axotomy decreases and that DHT enhances calbindin immunoreactivity in N.IX-X. Axotomy-induced decrease in calbindin immunoreactivity precedes cell loss in N.IX-X and may impair the capacity of motor neurons to regulate cytoplasmic calcium. Androgen-mediated maintenance of calbindin expression is thus a candidate cellular mechanism for trophic maintenance of hormone target neurons.

Primary- and secondary-like jaw-muscle spindle afferents have characteristic topographic distributions.

Single jaw-muscle spindle afferent axons were characterized physiologically and intracellularly stained to determine whether particular physiological types of spindle afferent show distinctive morphologies. Microelectrodes filled with either horseradish peroxidase (HRP) or biotinamide (Neurobiotin) were advanced into the mesencephalic trigeminal nucleus (Vme) in anesthetized rats. Intracellular recordings then were characterized by their response: to palpation of the jaw muscles; when pressure was applied to the teeth and during passive ramp and hold and sinusoidal jaw movement. Seventy-one afferents were characterized physiologically and injected with HRP; an additional 61 afferents were typed and injected with biotinamide. The response of 43 stained neurons was recorded in the presence of suxamethonium. The major projection areas of these afferents were the: trigeminal motor nucleus (Vmo); region dorsal to Vmo; reticular formation, spinal trigeminal nucleus, superior cerebellar peduncle and Vme. One afferent type was modulated strongly during stretching of the jaw-elevator muscles. Based on their high sensitivity during stretching of the jaw muscles and/or their silencing during the release phase of muscle stretch, these afferents were classified as primary-like spindle afferents. These afferents projected most strongly to Vmo. A second type of afferent was modulated only modestly during stretching of the jaw-elevator muscles. These tonic afferents were classified as secondary-like spindle afferents because of their low dynamic sensitivity during ramp muscle stretch and their continued discharge during the release phase of muscle stretch. Secondary-like afferents projected most strongly to the region dorsal to Vmo. Boutons (n = 3,834) from 11 afferents were studied in detail. Secondary-like afferents had statistically larger boutons within Vmo. In both secondary- and primary-like spindle afferents, only a small number of boutons were associated closely with the somata and proximal dendrites of trigeminal motoneurons. In these cases, however, two to five boutons appeared to contact individual motoneurons, implying multiple monosynaptic inputs to a selective subset of jaw-elevator motoneurons. Some "giant" boutons were present dorsal to Vmo and in Vme. These results demonstrate that dynamically sensitive and nondynamically sensitive jaw-elevator muscle spindle afferents project preferentially to different regions. Primary-like spindle afferents are capable of providing feedback related to the dynamic phases of muscle stretch and project most heavily to Vmo. Secondary-like spindle afferents can transmit a feedback signal associated with muscle length and project most strongly to the supratrigeminal region. Both types of afferent have projections caudal to Vmo that may serve longer latency jaw-muscle stretch reflexes and/or the projection of proprioceptive information to the thalamus and cerebellum.

Neonatal androgen and estrogen treatments masculinize the size of motoneurons in the rat spinal nucleus of the bulbocavernosus.

1. Newborn female rats were injected with either a nonaromatizable androgen, dihydrotestosterone propionate (DHTP; 1 mg), or estrogen benzoate (EB; 100 micrograms), or both, or sesame oil vehicle only as a control. In the first experiment, females were injected only on the day of birth (day 1). In the second experiment, females were given daily injections on either days 1, 3, and 5 of life or on days 6, 8, and 10. At 60 days of age the animals were sacrificed and the size of the somata and nuclei of motoneurons in the spinal nucleus of the bulbocavernous (SNB) was determined. 2. As in earlier studies, neonatal EB had no effect on the adult numbers of SNB cells, and the present study demonstrated estrogen's ineffectiveness in this regard in either the absence or the presence of DHTP. Nor did neonatal estrogen influence the survival of the SNB target musculature. 3. In agreement with previous studies, early DHTP treatment resulted in more SNB cells in adulthood and both late and early neonatal treatment with DHTP also resulted in larger SNB cells in adulthood. 4. We report for the first time that neonatal EB treatment also resulted in larger adult SNB cells. EB exerted this effect after a single injection on the day of birth or after multiple injections during the early neonatal period (days 1-5) but not after late neonatal injections. 5. These data suggest that both androgens and estrogens normally act to masculinize the size of SNB motoneurons, while only androgens affect the number of SNB cells.

Schwann cell-neuron relationships in spinal cord gray matter

Schwann cells develop within the ventral gray matter following exposure of lumbosacral spinal cords to x-rays in early postnatal rats. These ventral gray matter Schwann cell aggregates occurred in about 40% of the animals 8 or more weeks following irradiation. Light microscopically these cells appeared to be apposed to somata of large motor neurons, raising a question regarding the fate of axo-somatic synapses. This study focused on neuron-Schwann cell relationships and demonstrated ultrastructurally that the intraspinal Schwann cells established a variety of relationships with the neuronal somata and primary dendrites. These relationships ranged from direct contact without an intervening basal lamina to the presence of synaptic contacts intervening between neuron and Schwann cell basal lamina. Occasionally, the Schwann cells occupied an intermediate position between neurons and blood vessels, suggesting functions similar to those carried out by astrocytes. In these instances, as in all cases of Schwann cell-blood vessel contact, the vessels lacked their normal investiture by astrocytes. Light microscopic evaluation of synaptophysin-immunostained sections revealed decreased immunoreactivity in neuropil occupied by the Schwann cells but confirmed the presence of synapses on neuronal somata. Possible mechanisms underlying Schwann cell induction in the ventral gray matter are discussed. An understanding of the interactions between Schwann cells and the cellular constituents of the gray matter is important in light of attempts to enhance repair in the central nervous system by transplanting Schwann cells into that environment.

Serotonergic neurotransmission in the spinal cord and motor cortex of patients with motor neuron disease and controls: quantitative autoradiography for 5-HT 1a and 5-HT 2 receptors

Serotonin 5-HT is a potent modulator of motor neuron excitability in the spinal cord. Serotonergic neurotransmission, because of its effects on glutamatergic excitation, may be relevant to the pathogenesis and therapy of motor neuron disease (MND). The human motor system was studied at two levels, spinal cord and motor cortex, by autoradiography for the 5-HT 1A and 5-HT 2 receptor subclasses. In addition, biochemical estimations of indole metabolites were performed in the spinal cord. Post mortem tissue from control cases and MND patients showed a reduction in 5-HT 1A receptor binding in the cervical ( p < 0.01) but not lumbar ventral horn in MND. 5-HT 2 receptors were preserved in the ventral horn at both levels and were focally abundant around motor neuron somata. Tissue levels of 5-HT were unchanged in the spinal cord in MND. The metabolite 5-HIAA was increased in the cervical spinal cord in MND as was the molar ratio of 5HIAA:5-HT, implying that there may be an increased turnover of 5HT. In the motor cortex and premotor cortex the 5-HT 1A receptor remained unchanged in MND. There was a 20% reduction in 5-HT 2 receptor binding sites ( p < 0.05) across all the cortical laminae with preservation of the normal pattern of laminar binding. These changes in two levels of the motor system in MND most likely represent physiological adaptations in the spinal cord and motor cortex rather than primary involvement of the serotonergic system in the pathogenesis of the disease.