Quantitative ultrastructural analysis of the periaqueductal gray in the rabbit

The fine structure of the periaqueductal gray (PAG) of the rabbit was examined using the transmission electron microscope. On the basis of synaptic polarity, vesicle size, and the nature of the pre- and postsynaptic elements, 10 essentially different synaptic types could be discerned (6 axo-dendritic, 2 axo-somatic, 1 axo-axonic, and 1 dendro-dendritic). Synaptic contact on the soma of PAG neurons were small and covered, on average, only 1.6% of the soma surface. The most striking feature of the synaptic structure of the PAG was that more than 94.1% of all synapses were axo-dendritic. Of these, 83.5% were of the symmetrical type. Most of these contacts occurred on buttons of small to medium size, and contained either round vesicles of medium size or pleomorphic vesicles of medium size. Boutons containing only flattened vesicles were quite rare. Boutons contacting larger dendrites were generally small-to-medium in size, made asymmetric-type synaptic contacts, and contained pleomorphic vesicles of medium-to-large size. Medium-sized dendrites were contacted principally by small boutons exhibiting either symmetrical or asymmetrical junctions containing medium-sized pleomorphic vesicles, and in addition a few of these boutons contained both large, and small, round vesicles. Dendritic spines were generally provided with only one synaptic contact, stretching the entire width of the spinous process. Boutons and the spines on dendrites were approximately the same size. Synapses between two vesicle-containing structures (axo-axonic or dendro-dendritic synapses) were rare (1.4%). They were generally asymmetric and contained round vesicles of medium size. Complex synapses, where a glial sheet enclosed the synapse, were occasionally observed. Also seen were multiple synapses, with up to 11 contacts on a single dendritic profile. Large dense-core vesicle were seen in approximately 40% of all synapses, whereas small dense-core vesicles were only found in about 3%. Data is provided on how different synaptic features relate to ventral, lateral, dorsal, and medial PAG. Principally this is in relation to neuron size, glia cell content, axonal characterization, and vesicular type. © 1993 Wiley-Liss, Inc.     

Morphological correlates of synaptic transmission in lamprey spinal cord.

The dye Procion brown was used to identify in the light and electron microscope, synaptic contacts made between monosynaptically coupled neurons in the lamprey spinal cord whose synaptic interaction had been recorded. Synaptic contacts were made on different dendrites of the postsynaptic cell at different distances from the soma. Some of the contacts were made on dentritic spines and some on the smooth shaft of the dentrites. Serial sections through synaptic contacts made on dendritic processess of the postsynaptic cells were used for three-dimensional reconstruction of the synapses using computer graphics techniques. The computer reconstructions and detailed examination of the serial EM micrographs revealed the large proliferation of membrane involved in making these en passant synapses as well as the morphological changes due to stimulation of the presynaptic axon. These changes include depletion of synaptic vesicles and formation of complex vesicles and synaptic cisternae. Besides chemical synaptic contacts, four electrotonic contacts were located, confirming the mixed electrochemical synaptic response recorded from the postsynaptic cell. The mean quantum content was estimated and compared with the estimate of the available transmitter pool, assuming the quantal release hypothesis applies at these synapses. The total transmitter pool was estimated by counting all synaptic vesicles in all synaptic contacts. It was estimated that about 6% of the total transmitter pool is available for release at these synapses. This compares with less than 1% at the neuromuscular junction and about 20% at sympathetic synapses. These results support the hypothesis that synaptic vesicles may be recycled as described by Heuser and Reese (22) at the neuromuscular junction. Ongoing studies are investigating the effect on a variety of synaptic junctions to stimulation for different periods of time of presynaptic axons. The methods described in this study can also be used to test the models of synaptic interaction on dendritic trees described by Rall (39) and Jack and Redman (24).     

Distribution of synapses on an intracellularly labeled small pyramidal neuron in the cat motor cortex

Summary The morphological characteristics and distribution of synapses on a small pyramidal neuron in layer III of the cat motor cortex have been studied by combining intracellular HRP staining and electron microscopic examination. The stained neuron showed spiny apical and basal dendritic profiles under the light microscope, and exhibited the morphological features of a pyramidal neuron. Ultrastructural analysis indicated that about 80% of the presynaptic terminals formed asymmetrical synapses with spines of distal apical and basal dendrites. On proximal apical dendrites, 64% of the synapses were found to make contact with spines, and 16.7% of the synapses were of symmetrical type and formed with dendritic shafts. Two types of terminal could be identified on the soma; they were alternately located and established symmetrical and asymmetrical synaptic contacts respectively. Possible functional implications are discussed.This paper is dedicated to Professor Fred Walberg on the occasion of his 70th birthday.     

Ultrastructure of the rectifying electrotonic synapses between giant fibres and pectoral fin adductor motor neurons in the hatchetfish

Summary Synapses formed by giant fibres on pectoral fin adductor motor neurons were identified by horseradish peroxidase (HRP) injection. The synapses were distributed in clusters on the somata and proximal dendrites of the motor neurons. All of the labelled synapses contained synaptic vesicles and often had clearly defined active zones characteristic of chemical synapses. Some synapses also showed gap junctions with the motor neuron soma, often directly adjacent to an active zone. The gap junctions were asymmetrical, with a thick layer of electron dense material on the postsynaptic side. Previous electrophysiological data indicate that giant fibre inputs to motor neurons are purely electrotonic and that these electrical synapses rectify.     

Electron microscopic study of GABA-immunoreactive neuronal processes in the superficial gray layer of the rat superior colliculus: their relationships with degenerating retinal nerve endings

Summary GABA-immunoreactive neuronal elements were detected in the stratum griseum superficiale or superficial gray layer of the rat superior colliculus in an electron microscopic study, using postembedding immunocytochemistry with protein A-gold as a marker. In addition to neuronal somata, two types of GABA-immunoreactive neuronal processes were observed. Numerous profiles of axon terminals (1 m in diameter) with clear round or pleomorphic synaptic vesicles and mitochondria were found to establish mostly symmetrical synaptic contacts with GABA-immunonegative dendrites of various diameters. Some axosomatic synapses could also be observed. The gold particle density in this axon terminal compartment was between seven and 13 times the background level. The stratum griseum superficiale also included GABA-immunoreactive dendrites, some of which contained clear synaptic vesicles. These dendritic profiles always formed the presynaptic component of dendrodendritic synaptic contacts. The density of the gold particles in the dendritic compartment, taken as a whole, was between three and 13 times the background level. Furthermore, the relationship between the GABA-immunoreactive neuronal elements and degenerating retinal nerve endings identified in the left stratum griseum superficiale following enucleation of the right eye was investigated after a 7-day survival period. The profiles of degenerating retinal nerve endings (0.7 m in diameter) were found to be devoid of any specific labelling. Most of the retinal boutons established axodendritic synapses of the asymmetrical type with an immunonegative dendrite, which was also contacted in some cases by a GABA-immunopositive axon terminal. Other retinal endings were presynaptic to GABA-immunopositive dendritic profiles with synaptic vesicles, some of which were found to contact in turn an unlabelled dendrite, thereby completing serial synaptic relationships. More rarely, retinal endings formed the presynaptic component of possible axoaxonic synapses with GABA-positive terminals presumed to be axonic in nature. It can be concluded that the retinal input to the superficial gray layer often converges with a GABAergic axonal input on a dendritic target, the neurotransmitter specificity of which is unknown. In other cases, retinal terminals synaptically contact GABA-immunolabelled conventional and presynaptic dendrites and probably also some axon terminals; this might provide an anatomical substrate for the control of GABA release from these GABAergic processes. These results indicate that transmitter GABA plays an important role in retinocollicular transmission.     

GABAergic innervation of rat abducens motoneurons retrogradely labelled with HRP: quantitative ultrastructural analysis of cell bodies and proximal dendrites

Summary In this quantitative electron microscopic study we investigated the distribution of GABA axon terminals on rat abducens motoneurons by combining retrograde labelling of motoneurons with post-embedding immunodetection of GABA. We analysed the synapses on 13 cell bodies and 60 proximal dendritic profiles distributed along the entire rostro-caudal extent of the nucleus. For each of these two compartments, we analysed 1754 and 1176 axon terminals in contact with 6042 and 3299 m of postsynaptic membrane. The axon terminals were classified as Sv-type (containing spherical vesicles) or Pv-type (containing pleomorphic vesicles). The GABAergic terminals contained pleomorphic vesicles and established mainly symmetrical synaptic contacts. Their apposition lengths were greater than those of unlabelled terminals. On cell bodies, the percentage of GABAergic synaptic covering varied from 2.5% to 14.1% and the synaptic frequency of GABAergic axon terminals varied from 0.6% to 8.9%. These two parameters were significantly correlated with the diameter of the motoneurons. The percentage of synaptic covering and synaptic frequency were smaller on dendrites of small motoneurons than on those of large ones. The proximal dendrites of small motoneurons had a lesser GABAergic innervation than large ones. The total synaptic covering and frequency were smaller on somata than on dendrites. However, the percentage of synaptic covering by GABA terminals was higher on cell bodies than on proximal dendrites.     

The presence of membrane specializations indicative of somato-dendritic synaptic junctions in the optic tectum of the frog

Summary Somato-dendritic synaptic contacts were found between the perikaryon of stellate neurones and the dendrites of, presumably, pyramidal and pearshaped neurones in the optic tectum of the frog. According to the electron microscopic findings, the soma of stellate neurones is the presynaptic element. In a number of cases axo-somatic synapses were seen on the same neurones within a distance of 1–2 from the somato-dendritic synaptic contact. The synapsing axons are, probably, of tectal origin. It is assumed that the somato-dendritic synapsis is inhibitory in nature.     

Morphological study of cerebellar transplant cocultivated with cerebral cortical graft in the anterior eye chamber

Summary Morphological organization of Purkinje cells and of molecular layer of the cerebellar cortex cocultivated intraocularly with cerebral cortex for two months was studied. It was found, that while numerous spines on the main dendritic branches of Purkinje cells in single cerebellar grafts were vacant and non-synaptic, dendritic spines of thick Purkinje dendrites in double grafts were covered by large presynaptic bags. The resulting complex synaptic arrangement was strikingly similar although not identical to climbing terminals in normal (in situ) cerebellar cortex. Three distinct types of large presynaptic climbing-fibre like terminals were distinguished: (a) bouton with dense matrix and small round synaptic vesicles, (b) with large round vesicles and (c) containing ovoid synaptic vesicles. The spines of the thin, presumably tertiary dendritic branches were contacted mostly by one parallel axon varicosity, or — as a contrast to normal conditions-by axon terminal, containing ovoid synaptic vesicles. Irrespective of the shape of synaptic vesicles in the presynaptic terminal, all spine-synapses were of asymmetric type; in contrast, synapses on the dendritic shafts were always symmetric.GABA-immunogold reaction has revealed the presence of this inhibitory transmitter in most axon terminals containing ovoid-pleomorphic vesicles within the molecular layer, including those resembling climbing fiber-terminals. This shows a plasticity of the Purkinje cell dendrites to receive non-specific, foreign axons in the absence of specific afferents. Also, the type of synaptic junctions, i.e. whether symmetric or asymmetric, is determined exclusively by the postsynaptic neuron and is independent of the transmitter content of the presynaptic terminal.     

Axon hillocks and initial segments in spinal trigeminal nucleus with emphasis on synapses including axo-axo-axonic contacts

Summary As a part of a continuing study of the feline spinal trigeminal nucleus, the fine structure and synaptic arrangements on the axon hillock and axon initial segment of neurons in this region are described here. Transmission electron microscopy has been used to characterize qualitatively the axon hillock and initial segment and associated synapses in pars interpolaris. Axon hillocks and initial segments are easily identified in continuity with somata or as isolated profiles in the neuropil, and they receive synaptic contacts: these we regard as axo-axonic. The presynaptic terminals contain either mainly round or mainly flattened synaptic vesicles and have Type I (asymmetric) or Type II (symmetric) thickenings respectively at their contacts with the axon hillock or initial segment. I report here also the unusual arrangement of three separate axons in a serial synaptic complex. Some of the round vesicle Type I contacts onto the axon hillock-initial segment region also receive Type II contacts from one or more flattened vesicle terminals, thus formingan axo-axo-axonic complex. These flattened vesicle terminals lack the usual features of a presynaptic dendrite. It has been shown that in this nucleus some round vesicle terminals, especially those postsynaptic to flattened vesicle terminals, are primary afferents from the periphery. Therefore the round vesicle terminal presynaptic to the axon hillock-initial segment region, some of which are included in the axo-axo-axonic complex may also be a primary afferent directly contacting the spike generator area of the relay neuron and under presynaptic control of a flattened vesicle synapse. The latter may possibly be an intrinsic contact. This strategic situation of round vesicle terminals and the axo-axo-axonic complex at the axon hillock or initial segment has major implications relevant to the overall output of these neurons.     

Quantitative ultrastructure of synapses on functionally identified primary afferent neurons in the cat trigeminal mesencephalic nucleus

Though a number of studies have reported the presence of synapses on neurons in the trigeminal mesencephalic nucleus (Vmes), there have been no quantitative studies of either the density of innervation, or the ultrastructure, of the synapses on single, physiologically identified neurons in this nucleus. In this study we recorded from single neurons in the Vmes, identified them as being either muscle spindle afferents (MS) or periodontal ligament mechanoreceptor afferents (PL), and then labeled the neurons by intra-axonal injection of horseradish peroxidase (HRP). The material was first processed to reveal the HRP activity, following which ultrathin sections through the labeled somata were cut and examined under the electron microscope. Complete serial reconstructions were made through the soma of one MS neuron and one PL neuron, and the contacts on the neurons reconstructed. Boutons were found on the soma, spines, appendages and the axon hillock and the initial segment of the axon. The numbers of boutons terminating on the two neurons were 198 (PL) and 424 (MS), giving a packing density of 4.4 and 10.7 boutons respectively (i.e., number of boutons/100 micron 2 of the postsynaptic membrane). Boutons could be separated into two types on the basis of their vesicles: those containing clear, round vesicles (i.e., S-type) and those containing a mixture of round, oval and flattened vesicles (P-type). Ninety-five (PL neuron) and 99% (MS neuron) of terminals on the two neurons were P-type. All the S-type boutons and 80% of the P-type boutons formed asymmetric synaptic contacts while 10% of the P-type boutons made symmetric contacts. Quantitative measurements of the P-type boutons on the labeled neurons, in which the data of MS and PL neurons were pooled, revealed that bouton volume was highly correlated with bouton surface area, active zone number, total active zone area, vesicle number, and mitochondrial volume. However, comparing the quantitative measurements of the P-type boutons with those of previously reported vibrissa afferent terminals and their associated axon terminals revealed that all the parameters were smaller for the P-type boutons (on Vmes neurons) than those of the vibrissa afferent terminals but similar to those of axon terminals presynaptic to the vibrissa afferents. Taken together, our results emphasize the wide scope for synaptic interactions in the Vmes and suggest that it may be more fruitful to view the Vmes as an integrating center.     

Differences between the scaling of miniature IPSCs and EPSCs recorded in the dendrites of CA1 mouse pyramidal neurons

Anatomical studies have described inhibitory synaptic contacts on apical dendrites, and an abundant number of GABAergic synapses on the somata and proximal dendrites of CA1 pyramidal cells of the hippocampus. The number of inhibitory contacts decreases dramatically with distance from the soma, but the local electrophysiological characterization of these synapses at their site of origin in the dendrites is missing. We directly recorded dendritic GABA receptor-mediated inhibitory synaptic events in adult mouse hippocampal CA1 pyramidal neurons and compared them to excitatory synaptic currents recorded at the same sites. Miniature GABAergic events were evoked using localized application of a hyperosmotic solution to the apical dendrites in the vicinity of the dendritic whole-cell recording pipette. Glutamatergic synaptic events were blocked by kynurenic acid, leaving picrotoxin-sensitive IPSCs. We measured the amplitude and kinetic properties of mIPSCs at the soma and at three different dendritic locations. The amplitude of mIPSCs recorded at the various sites was similar along the somato-dendritic axis. The rise- and decay-times of local mIPSCs were also independent of the location of the synapses. The frequency of mIPSCs was 5 Hz at the soma, in contrast to < 0.5 Hz at dendritic sites, which could be increased to 10–20 Hz and 6–10 Hz, respectively, by our hyperosmotic stimulation protocol. Miniature glutamatergic events were evoked with the same protocol after blocking inhibitory synapses by bicucculine. The measured amplitudes increased along the somato-dendritic axis proportionally with their distance from the soma. The measured kinetic properties were independent of location. Consistent with the idea that IPSCs may have a restricted local effect in the dendrites, our data show a lack of distance-dependent scaling of miniature inhibitory synaptic events, in contrast to the scaling of excitatory events recorded at the same sites.     

Choline acetyltransferase immunoreactivity is localized to four types of synapses in the rat interpeduncular nucleus

Summary The cholinergic synapses of the rat interpeduncular nucleus (IPN) were demonstrated by immunostaining that utilized a monoclonal antibody directed against choline acetyltransferase. The rostral, central, intermediate and lateral subnuclei of the IPN each contained a single type of immunoreactive terminal. Immunoreactivity was localized to synaptic vesicle membranes, inner and outer mitochondrial membranes, the cytoplasmic surface of plasma membranes (especially at the contact zones), and longitudinal microtubules in preterminal portions of axons. Terminals were identified by comparison to previous studies of the synaptic organization of the IPN. In the rostral subnucleus, the immunoreactive terminals were characterized by their content of spherical vesicles, 45 nm in diameter, intermixed with moderate numbers of dense-cored vesicles, 75–100 nm in diameter. These terminals formed asymmetrical contacts. They correspond to the more numerous of the two types of axodendritic terminals described in this subnucleus, i.e. those which degenerate after lesions of the habenula. The moderate number of immunoreactive terminals in the lateral subnucleus contained pleomorphic vesicles, 30–45 nm in diameter. Up to three of these formed symmetrical contacts with individual dendrites, which ranged in diameter from 0.35 to 0.55m. The other types of axodendritic terminal in this subnucleus, which often contacted the same dendrites, were unstained. These latter terminals have been interpreted as being those which contain substance P. The immunoreactive terminals in the central subnucleus consisted of moderate numbers of S terminals. These contained spherical vesicles, 40–60 nm in diameter, and formed markedly asymmetricalen passant contacts with small dendritic processes or spines. The immunoreactive terminals in the intermediate subnucleus had the same presynaptic and contact morphology. Many were clearly crest synapses. The remainder appeared to be such, but seen only partially within the plane of section. In the intermediate subnucleus there were up to several hundred immunostained terminals per grid square in some sections.These findings are consistent with the existence of a dense cholinergic projection to the IPN. The crest and S synapses, both of which degenerate after lesions of the habenular region, are shown to be cholinergic as previously suggested. Additionally, demonstration of the cholinergic innervation of other subnuclei of the IPN increases understanding of the relation of cholinergic to other transmitters localized to various portions of this nucleus.On leave of absence from Semelweis University, Hungary.     

Aspiny neurons and their local axons in the neostriatum of the rat: a correlated light and electron microscopic study of Golgi-impregnated material

Summary Three types of neuron with smooth (aspiny) dendrites could be distinguished in the Golgi-impregnated rat neostriatum. Examples of each type of aspiny neuron were found with local axon collaterals within the neostriatum and these were selected for gold-toning and examination in the electron microscope. One type of aspiny neuron had an elongated, usually spindle-shaped, medium-size soma with two, or rarely three, primary dendrites originating from opposite poles of the cell; one example of this type of neuron had two separate axons. The second type of aspiny neuron had a nearly round, medium-size soma with four primary dendrites that branched profusely quite close to the cell body. A third type of aspiny neuron had a very large polygonal-shaped cell body. Afferent axon terminals were found in synaptic contact with the dendrites and cell bodies of all three types of aspiny neuron.Axon collaterals of each type of neuron displayed varicosities which, when examined in the electron microscope, were frequently found to be boutons making synaptic contact. All such synaptic contacts had symmetrical membrane specializations and the most common postsynaptic targets were dendritic shafts, sometimes spine-bearing. Dendritic spines themselves also received synapses from each type of neuron. No axosomatic synapses involving boutons of identified axons were found. One example of a synapse between an axon collateral of an aspiny neuron and one of the same neuron's dendrites (an autapse) was demonstrated by electron microscopy.It is concluded that the synaptic terminals of at least four types of neuron, the three aspiny types described here and the medium-size densely spiny neuron, participate in local circuit interactions in the neostriatum.     

Synaptic organization of the dorsal lateral geniculate nucleus in the adult hamster

Summary The synaptic organization of the sector of the dorsal lateral geniculate nucleus has been examined by electron microscopy in normal adult hamsters and in adult hamsters subjected to unilateral eye enucleation or intravitreal injection of horseradish peroxidase.Two types of neuropil are apparent. Islands of complex neuropil partially enclosed by astrocyte processes (synaptic glomeruli) are surrounded by a sea of simpler non-glomerular neuropil. The latter is dominated by small axon terminals with spherical synaptic vesicles and Gray type 1 axodendritic contacts (SR-boutons) and also contains axon terminals with flattened synaptic vesicles (F-boutons). The glomerular neuropil contains (i) exclusively postsynaptic dendrites and dendritic protrusions of presumptive projection cells; (ii) pre- and postsynaptic pleomorphic-vesiclecontaining P-boutons (interpreted as appendages of the dendrites of interneurons); (iii) large axon terminals containing spherical synaptic vesicles and large pale mitochondria (R-boutons) which were experimentally identified as retinal terminals and which are presynaptic to both projection cell dendrites and P-boutons at Gray type 1 contacts; (iv) F-boutons (minority component). F-boutons and P-boutons are presynaptic to both projection cell dendrites and P-boutons and P-boutons are the intermediate elements of various serial synapses including triplet (triadic) synapses. Medium-large terminals with spherical synatpic vesicles and dark mitochondria (RLD-boutons) which were commonly invaginated by dendritic spines of projection cells in small glomerulus-like formations were also identified. The origin of RLD-boutons is unknown but SR-boutons probably derive chiefly from ipsilateral visual cortex and possibly also from superior colliculus, and non-glomerular F-boutons probably originate in the ipsilateral thalamic reticular nucleus.No differences in synaptic organization were found between the part of the nucleus which receives uncrossed retinal input and the part which receives crossed input, nor were differences seen in the size, fine structure or relationships between the terminals of identified crossed and uncrossed retinal axons.     

Distribution of electrotonic synapses on identified lamprey neurons: a comparison of a model prediction with an electron microscopic analysis

1. Intracellular recordings of the monosynaptic excitatory postsynaptic potential (EPSP) were made from an identified giant interneuron in the lamprey spinal cord following stimulation of a single identified presynaptic giant axon. The EPSP had both electrotonic and chemical components. 2. The giant interneuron and sometimes the giant axon were labeled with horseradish peroxidase (HRP). Using combined light and electron microscopy (EM), gap junctions formed by the axon on the HRP-labeled dendritic trees of seven interneurons were identified and their position marked on dendritic diagrams made from tracings of the cells. 3. The total number of gap junctions on a giant interneuron varied from a minimum of 9 to a maximum of 23. The number of gap junctions on a branch of a dendritic tree varied from 1 to 9. For all seven neurons the closest gap junction was located approximately 65 microns from the soma and the furthest 280 microns from the soma. 4. When gap junction position was plotted as a function of electrotonic distance from the soma, the variability in their distribution decreased significantly. Synaptic location was found to be on the average about 0.5 space constants from the soma, and this value compared favorably with that determined from an analysis of half-width and rise time of the electrotonic synaptic potential for these neurons. 5. These results suggest that the presynaptic axon tends to make, on the average, synaptic contact at the same electrical distance from the soma.     

Identification of dorsal root synaptic terminals on monkey ventral horn cells by electron microscopic autoradiography

Summary The projection of dorsal root fibres to the motor nucleus of the macaque monkey spinal cord has been examined utilizing light and electron microscopic autoradiography. Light microscopy demonstrates a very sparse labelling of primary afferent fibres in the ventral horn. Silver grains overlying radioactive sources are frequently clustered into small groups, often adjacent to dendritic profiles. Under the electron microscope, myelinated axons and a few large synaptic profiles containing rounded synaptic vesicles were overlain by numerous silver grains. These labelled profiles made synaptic contact with dendrites 1–3 m in diameter. The labelled profiles did not contact cell bodies or large proximal dendrites of ventral horn neurons. Frequently, small synaptic profiles containing flattened vesicles were presynaptic to the large labelled terminals and it is suggested that these axoaxonal synapses may mediate presynaptic inhibition of the primary afferent fibres. The relationship of the present findings to previously published physiological and anatomical studies is discussed.     

The development of the inferior olivary complex in preweanling opossums

Summary Pre- and postsynaptic elements within the developing inferior olive (IO) of both control and experimental opossums were examined via electron microscopy. Electron dense boutons identified di-/mesencephalic, cerebellar and spinal afferents within the IO of 8–71 day old animals, which survived 4–48 hours following either midbrain hemisections or spinal transections.During its initial stage of development (3–22 days) the neuropil of the IO is segregated into fields of small diameter neurites or flocculent profiles. Within the fields of flocculent profiles, synaptic interactions are established, which are both infrequent and immature. Although some flocculent profiles are presynaptic, most are postsynaptic and emanate from olivary somata and dendrites. Synaptic contacts also occur with olivary somata, dendritic shafts, spines and dendritic varicosities. Clear round vesicles (crv's; 40 m) predominate within all boutons, normal ones as well as those which degenerate after di-/mesencephalic, cerebellar and spinal lesions; however, larger (70 m) dense cored vesicles (dcv's) are occasionally observed within some boutons. Degenerating terminals from all three sources primarily contact flocculent profiles and dendritic shafts.As the opossum matures (42 days) dramatic increases occur in the number and complexity of both pre- and postsynaptic elements. Marked variations are observed in the matrix density of dendritic shafts. Although all terminal boutons predominantly contain crv's, the number of dcv's within the population of presynaptic elements increases markedly. Concurently, olivary neurons are profusely studded with spines. Simple dendritic spines and spiny appendages as well as dendritic shafts are the most frequent postsynaptic structures within the principal nucleus (PO). Olivary somata and their spines, however, are postsynaptic to degenerating de-/mesencephalic afferents within the PO. Flocculent profiles, which persist within the accessory nuclei, and dendritic shafts are postsynaptic to degenerating spinal boutons.By 70 days of age synaptic contacts appear more mature and more nearly approximate those seen in the adult (King 1980). Few somatic contacts, opaque dendrites, dendritic varicosities, and flocculent profiles are evident within the PO. Dendritic shafts and spines are the principal postsynaptic structures. Many di-/mesencephalic and cerebellar afferents synapse within maturing synaptic clusters on spines between which a rare gap junction is observed. Other di-/mesencephalic and cerebellar endings in the PO as well as spinal endings in the accessory nuclei are presynaptic to dendritic shafts and spines external to synaptic clusters. This predilection for contacting more specific loci on olivary neurons provides good evidence for synaptic remodeling.As the olivary nuclei develop further, the incidence of gap junctions increases and pleomorphic vesicles appear within boutons. The glial investment of neuronal elements, including synaptic clusters, also becomes more extensive.In conclusion, early di-/mesencephalic, cerebellar and spinal synaptic contacts appear qualitatively uniform in their synaptic features and postsynaptic interactions. As olivary development proceeds, however, the distinguishing synaptic features of the nuclear complex become more apparent. Synaptic remodeling occurs as some midbrain and cerebellar terminals are localized within synaptic clusters. The ultrastructural features characteristic of the adult IO are finally achieved by 80 days of age.This research was supported by N.I.H. Research Grant NS-08798     

Distal dendrites of frog motor neurons: a computer-aided electron microscopic study of cobalt-filled cells

Summary With the aid of the cobalt labelling technique, frog spinal cord motor neuron dendrites of the subpial dendritic plexus have been identified in serial electron micrographs. Computer reconstructions of various lengths (2.5–9.8 m) of dendritic segments showed the contours of these dendrites to be highly irregular, and to present many thorn-like projections 0.4–1.8 m long. Number, size and distribution of synaptic contacts were also determined. Almost half of the synapses occurred at the origins of the thorns and these synapses had the largest contact areas. Only 8 out of 54 synapses analysed were found on thorns and these were the smallest. For the total length of reconstructed dendrites there was, on average, one synapse per 1.2 m, while 4.4% of the total dendritic surface was covered with synaptic contacts. The functional significance of these distal dendrites and their capacity to influence the soma membrane potential is discussed.     

A cholinergic model synapse to elucidate protein function at presynaptic terminals

A large number of proteins have been identified at nerve terminals and a cascade of protein-protein interactions has been suggested to be involved in cycling of synaptic vesicle states. To explore protein function in presynaptic terminals, only a few unique synapses such as the squid giant synapse, the calyx of Held synapse and the hippocampal neuron autapse have been used. The squid giant synapse and the calyx of Held are useful to introduce reagents into their large presynaptic terminals and the hippocampal neuron autapse is a good system to modify a protein level by exogenous DNA or RNA. The cholinergic synapse formed between superior cervical ganglion (SCG) neurons in long-term culture is a useful model for a fast synapse. The axon of the large cell body contacts with soma of neighboring neurons. The architecture of synaptic connections makes it possible to introduce reagents into the presynaptic terminals by diffusion from a cell body within a short time. Introduction of exogenous cDNA or siRNA performed by microinjection into a SCG neuron allows us to modulate the level of the protein of interest or to express mutant proteins in the neuron. Here, we describe use of the model SCG neuronal synapse to elucidate function of presynaptic proteins in mediating synaptic transmission.     

Fine structure of synapses associated with characterized postsynaptic dorsal column neurons in the cat

Fourteen dorsal horn neurons with axons projecting through the dorsal columns were identified either by electrophysiological methods (and subsequently injected with horseradish peroxidase) or by retrograde labelling with horseradish peroxidase in cats. All neurons were contacted by small (less than 2 micron) boutons containing spherical or elongated agranular vesicles. One neuron with its soma located in lamina III received additional contacts from central elements of glomerular complexes. Neurons with somata located more ventrally (deep lamina IV and V) were also postsynaptic to large (greater than 2 microns) electron lucent profiles which formed multiple synapses with the labelled cells. Some boutons presynaptic to postsynaptic dorsal column neurons were themselves postsynaptic to profiles containing pleiomorphic agranular vesicles at axoaxonic synapses. They also occasionally participated in triadic complexes. It is concluded that the synaptic arrangements formed by boutons in association with postsynaptic dorsal column neurons differ significantly from those associated with spinocervical neurons. Such differences might provide the anatomical substrate for the observed receptive field characteristics of these neurons.