Synaptic organization in the adult ferret medial superior olive

The ultrastructure of the medial superior olive (MSO) was studied in the adult ferret. The synaptic terminals were categorized on the basis of morphology and their distribution determined. There are three types of synaptic terminals: R terminals, containing round vesicles; Ov terminals, containing ovoid vesicles; and P terminals, containing vesicles of varying morphologies. R terminals are the dominant terminal type on both the somata and dendrites. Ov and P terminals are equally prevalent on the dendrites; however, P terminals are significantly more common than Ov terminals on the somata. Furthermore, P terminals are significantly more common on the somata than on the dendrites. These results suggest that there is some segregation of types of afferent synapses on MSO cells.

Fine structure of the magnocellular subdivision of the ventral anterior thalamic nucleus (VAmc) of Macaca mulatta: II. Organization of nigrothalamic afferents as revealed with EM autoradiography

An EM-autoradiographic technique was used to identify the ultrastructural features and synaptic sites of nigral afferents to the ventral anterior nucleus pars magnocellularis (VAmc) of the rhesus monkey thalamus. The findings demonstrate that the nigral boutons are of medium-sized to large, with the majority being of the en passant type. These boutons form symmetric synaptic contacts, and contain pleomorphic or entirely flat vesicles and numerous mitochondria. The nigral input is heavily biased towards thalamocortical projection neurons (PN), whose somata and dendrites represent about 82% of the postsynaptic sites of labeled boutons. The distal dendrites of local circuit neurons (LCN) comprise 13% of the postsynaptic sites. Nigral terminals appear to represent a single extrinsic afferent input to the somata and primary dendrites of thalamocortical projection neurons. A nigral input to LCN somata was not demonstrated but the possibility could not be excluded. Although the basic ultrastructural features of nigral boutons in the monkey are similar to those described earlier in the cat (Kultas-Ilinsky et al.: J. Comp. Neurol. 216:390-405, '83), essential species differences exist in the intensity of the nigral input and its distribution on thalamic neurons.

Thyrotropin-releasing hormone-immunoreactive nerve terminals synapse on the dendrites of gastric vagal motoneurons in the rat

Thyrotropin-releasing hormone stimulates vagally mediated gastric acid secretion and motility by an undefined central mechanism in the rat. The present study sought to determine the anatomical basis for this stimulatory effect by examining the ultrastructural relationship of nerve terminals immunoreactive for thyrotropin-releasing hormone with the dendrites of gastric vagal motoneurons. A light and electron microscopic double immunostaining technique was employed using the beta subunit of unconjugated cholera toxin as a neural tracer. Cholera toxin (50 microliters, 0.25%) was injected into the ventral stomach musculature in five rats. After 72 hours' survival, animals were sacrificed by transcardiac perfusion fixation. Retrogradely transported cholera toxin was immunocytochemically localized in vagal gastric motoneurons and their dendrites in the dorsal motor nucleus of the vagus and nucleus of the solitary tract, alone or in combination with the immunocytochemical localization of thyrotropin-releasing hormone. Ultrastructural analysis of double-labeled material revealed thyrotropin-releasing hormone-immunoreactive nerve terminals making asymmetric synaptic contacts on the retrogradely labeled dendrites of vagal gastric motoneurons. Nerve terminals immunoreactive for thyrotropin-releasing hormone also made asymmetric and symmetric synaptic contacts with unlabeled dendrites of undetermined perikaryal origin. In addition, nonsynaptic varicosities immunoreactive for thyrotropin-releasing hormone were frequently observed in the vagal nuclei. The synaptic contacts between thyrotropin-releasing hormone-immunoreactive nerve terminals and vagal gastric motoneuronal dendrites provide one possible basis for the profound stimulatory effect of central thyrotropin-releasing hormone on gastric vagal motor activity.

Synaptic organization of neurotensin immunoreactive amacrine cells in the chicken retina

Immunohistochemistry was utilized to investigate the light and electron microscopic localization of neurotensinlike immunoreactive (NT) amacrine cells in the chicken retina. The NT cells possess oval cell bodies (7 microns in diameter) that are located in either the second or third tier of cells from the border of the inner nuclear and inner plexiform layers. The processes of such cells extend into the inner plexiform layer where they ramify as a narrow plexus in sublamina 1 and as a broad plexus in sublaminas 3 and 4. Additionally, stained processes are observed occasionally within sublamina 5. At the ultrastructural level, NT-positive somas exhibit a rather dense and evenly distributed peroxidase reaction product throughout their cytoplasm. The nucleus of NT amacrine cells possess a round, unindented nuclear membrane. NT-immunoreactive processes in the inner plexiform layer interact synaptically only with non-NT cells. NT processes receive synaptic input mainly from the processes of amacrine cells and to a lesser degree from bipolar cells. The large majority of NT-stained varicosities form presynaptic contacts onto the processes of amacrine cells, but are also presynaptic to bipolar cell axon terminals. Moreover, each of the above synaptic relationships can be identified in each of sublaminas 1 and 3 to 4 of the inner plexiform layer. In addition, NT processes are presynaptic to processes devoid of synaptic vesicles that may originate from ganglion cells. Finally, NT processes occasionally form synaptic contacts onto somas situated in the most proximal row of the inner nuclear layer.

Proteolysis is a critical step in the physiological stop pathway: mechanisms involved in the blockade of axonal regeneration by mammalian astrocytes

Regenerating axons of adult dorsal roots are stopped by reactive astrocytes at the PNS-CNS junction. While it has been suggested that the astrocytes might pose a physical barrier to axonal growth, based on ultrastructural comparisons of physically blocked and axo-glial endings, it was proposed that astrocytes in the root transitional zone block axonal growth by activating the physiological stop pathway within the growing axon tips. Part of the stop pathway involves the proteolytic breakdown and removal of neurofilaments as they enter the axon endings. Another component involves the establishment of anterograde-to-retrograde conversion for the removal of membranous elements from the axonal endings. Both of these components appear to be dependent upon the activation of proteases within the axon tips. Therefore, to further test our hypothesis we infused, by intrathecal catheterization, the region of the dorsal root transitional zone with the protease inhibitor leupeptin at a time when the majority of regenerating axons have terminated in the region. Ultrastructural analyses after leupeptin treatment revealed axo-glial endings distended by accumulations of neurofilaments and organelles, particularly tubulovesicular profiles. These observations further support the idea that astrocytes, like normal target cells, can activate the physiological stop pathway.

Different kinds of axon terminals forming symmetric synapses with the cell bodies and initial axon segments of layer II/III pyramidal cells. I. Morphometric analysis

An examination of material prepared for conventional electron microscopy has indicated that there are at least four different types of axon terminals forming symmetric synapses with the cell bodies and initial axon segments of layer II/III pyramidal cells in the rat visual cortex. One type of terminal synapses with the initial axon segment and it is derived from the chandelier cell. Because the location and features of these terminals allow them to be readily recognized, chandelier cell terminals were used to determine the extent of morphometric variability that can exist among terminals originating from one cell type. It was found that there is a wide range of mean synaptic vesicle size among chandelier terminals, so that calculated mean vesicle profile diameters for individual terminals can be between 32 and 39 nm. Similar ranges of mean synaptic vesicle sizes also exist among populations of the other three axon terminal types. These terminal types are referred to as 'large', 'medium-sized', and 'dense' terminals. The large terminals synapse with the cell bodies of layer II/III pyramids and their profiles often measure 1.5 X 0.8 microns. The large terminals contain rather loosely packed pleomorphic vesicles and they frequently synapse with a second neuronal element. The medium-sized terminals are smaller, being 1.0 X 0.6-0.8 microns in size, and their synaptic vesicles are usually more closely packed than those within the large terminals. The medium-sized terminals are the ones encountered most frequently on the cell bodies of pyramidal cells and they can also occur on the axon hillock and initial axon segment. The dense terminals are usually flattened against the cell body, and they contain rather rounded and closely packed synaptic vesicles, which often seem to be enmeshed in a rather dark cytoplasmic matrix. This matrix and the close packing of the vesicles makes these terminals appear to be more dense than the others. It is now necessary to determine the origins of the large, medium and dense terminals, and to ascertain if they all use GABA as their neurotransmitter.

Rapid refilling of neurosecretory terminals with secretory granules after an acute stimulus to the isolated neural lobe of the rat

Quantitative ultrastructural techniques were used to study changes in the distribution of intracellular organelles in neurosecretory terminals of the rat neurohypophysis during recovery from a depolarising stimulus in vitro. The volumetric density of neurosecretory granules which, in profiles of nerve terminals sectioned through the area of contact with the basal lamina, was decreased as a result of stimulation, returned to control values within 2 h after cessation of stimulation. We conclude that, even in the absence of the cell body and action potentials propagated from it, granules can migrate quickly within the terminal region of the neurosecretory axons to refill a depleted compartment.

Correlation of monosynaptic field potentials evoked by single action potentials in single primary afferent axons and their bouton distributions in the dorsal horn

The relationship between structure and function of the projections of single identified primary cutaneous axons was investigated by recording cord dorsum potentials at 4 sites in response to electrical stimulation of the single axon and visualizing the boutons of the axon stained by intracellular injection of horseradish peroxidase. The rostrocaudal extent of boutons differed from fiber to fiber ranging from 4.14-11.50 mm; their location in the dorsal horn also varied in agreement with the known somatotopy of the presynaptic neuropil and dorsal horn neurons. Rostrocaudal distributions of cord dorsum potentials and boutons of individual fibers revealed good agreement. Cord dorsum potential amplitude and length of the spinal projection were positively correlated with number of boutons, but no correlation with bouton density was found. The spinal projection of afferents innervating slowly adapting type 1 mechanoreceptors exhibited a greater rostrocaudal extent (mean: 8.48 mm) than those innervating rapidly adapting mechanoreceptors (i.e., hair follicle and field receptors: mean: 5.87 mm). Although the mean total number of boutons was greater for axons with slowly adapting receptors (7,250/fiber) than for axons of rapidly adapting receptors (4,677/fiber), no differences in the longitudinal density of boutons (boutons/mm) were observed. Likewise, summed amplitudes of cord dorsum potentials at the 4 recording electrodes were larger for SA1 afferents than for those of field and hair follicle afferents. A major role for the number of boutons in determining these differences is supported by the finding that the calculated average contribution per bouton to cord dorsum potentials (expressed as an amplitude coefficient a) was similar for slowly and rapidly adapting afferents. No evidence was found for regions in which boutons did not contribute to the cord dorsum potential.

Intramembrane particles and responses of sensory axon terminals during reinnervation of the frog muscle spindle

Changes in the density of intramembrane particles (IMPs) of sensory nerve terminals in the bullfrog muscle spindle were correlated with recovery in the response of the spindle to stretch during postcrush reinnervation. A few IMPs on the protoplasmic (P) face in summer experiments (June to October) reappeared by the 3rd week after the nerve crush, then rapidly increased to 110% and 120% of control values 2 and 2.5 months after the crush. Afferent responses to stretch could be recorded after the mean IMP density on the P-face in terminal branches had recovered to more than 25% of the control value. The discharge rate showed a plateau pattern during the period of the excessive IMPs. This was supplanted by a normal pattern after a myelinated branch of the sensory axon was cut. The IMPs in winter experiments (November to April) reappeared by day 90 after nerve crush, and then slowly increased. The sustained responses to stretch reappeared after 5 months, when the mean IMP density on the P-face was restored to 25% or more of the control. Neither excessive density of the IMPs nor plateau pattern of the discharge rate were observed in winter experiments. The relation between the regenerated IMP densities and the functional recovery is discussed.

Transplantation of the pineal gland in the mammalian third cerebral ventricle

Fine structural correlates and functional parameters were measured in pinealectomized rats following grafting of the pineal gland into the third cerebral ventricle. Pinealectomy caused a significant decrease in serum melatonin concentration of animals compared to that in normal controls. No significant difference was observed in the serum melatonin concentration between pinealectomized rats and those receiving sham transplantation with fragments of occipital cortex. By 6 weeks nearly 50% of pinealectomized rats receiving pineal transplants demonstrated a significant increase in the serum melatonin concentration in contrast to that of pinealectomized rats and pinealectomized animals receiving sham transplants. Pinealocytes survived and flourished following transplantation from the epithalamic region to the third cerebral ventricle of the hypothalamus in host rats. These cells were found to be arranged individually or in clusters surrounding fenestrated capillaries of the graft. Moreover, these pinealocytes demonstrated ultrastructural features indicative of an active secretory process, including dense-core and clear vesicles as well as vacuoles containing flocculent material. Additional characteristics distinctive of normal control pinealocytes were observed in surviving cells of grafts, such as synaptic ribbons, synaptic ribbon fields, and myeloid bodies. Bundles of unmyelinated axons and apparent adrenergic nerve endings were observed with transmission electron microscopy and immunocystochemistry using antisera against tyrosine hydroxylase (TH). Nerve fibers and terminals were found within perivascular spaces surrounding fenestrated capillaries of viable grafts. These reported observations suggest that a significant population of transplanted pinealocytes recover functional activity (e.g., heightened melatonin secretion) following stereotaxic grafting into the third cerebral ventricles of pinealectomized animals. This apparent recovery of function may be linked directly to reinnervation of the gland by nerve fibers that appear to arise from the underlying median eminence.

Quantitative ultrastructural tannic acid study of the relationship between electrical activity and peptide secretion by the bag cell neurons of Aplysia californica

Release of neurosecretory material by the neuroendocrine bag cells (BC) of the gastropod Aplysia californica was studied, using quantitative electron microscopy and the tannic acid method for the demonstration of exocytosis of neuropeptides. Axon terminals of electrically inactive BC located in the periphery of the pleurovisceral connectives are filled with secretory granules and show low exocytosis activity (one exocytosis figure per 8 terminal profiles). In terminals of BC stimulated to an electrical discharge, in contrast, granules are scarce or absent and exocytosis activity has increased 24-fold. During rest and, particularly, during electrical discharge, BC apparently release secretory material into the hemolymph by exocytosis from axon terminals. Release furthermore takes place from axons running in the connective tissue surrounding the connectives.

Terminals of group Ia primary afferent fibres in Clarke's column are enriched with L-glutamate-like immunoreactivity

Group Ia muscle spindle afferent fibres form giant terminals in Clarke's column which can be identified by morphological criteria. Postembedding Immunogold reactions were performed on tissue from the column using antiserum which recognized fixed L-glutamate in tissue. Giant terminals were heavily labelled with gold particles and quantitative analysis revealed that they contained significantly higher concentrations of L-glutamate in comparison with adjacent structures. L-Glutamate-enrichment of giant boutons is further evidence supporting the idea that this amino acid is a neurotransmitter at Ia synapses.

Identification of pedicles of putative blue-sensitive cones in the human retina

Cone photoreceptor pedicles from midperipheral regions of the human retina (6 mm from the foveal center) have been studied by light and electron microscopy. Three areas of cone pedicle mosaic were serially thin-sectioned, in the tangential plane, from the inner border of the outer plexiform layer to the emergence of the cone axons from the cone pedicles. Semithin sections were then collected from the cone axon level through the cone cell bodies to the cone inner segment level. Two hundred twenty-one cone pedicles were followed by this means to their respective inner segments. Eight percent of the cone pedicles were from cones with inner segment characteristics of the blue cones. All 221 cone pedicles were reconstructed by tracing images from electron micrographs. The cone pedicle locations, surface areas, telodendrial projections, and synaptic ribbons could then be measured by morphometry and analyzed by statistical methods. Some selected cone pedicles were reconstructed by computer graphics methods. The cone pedicles identified as belonging to the blue cone type could be distinguished from the surrounding longer wavelength types on the following morphological criteria: 1) they were smaller (50% the area of the surrounding pedicles), 2) they contained shorter synaptic ribbons, 3) they exhibited essentially no telodendrial contact to neighboring cone pedicles, 4) they were positioned slightly more vitread in the outer plexiform layer than neighboring pedicles, and 5) their irregular occurrence in the cone mosaic coincided with the distribution criteria established in our previous paper (Ahnelt et al: J. Comp. Neurol. 255:18-34, '87) for putative blue sensitive cones in midperipheral human retina.

3-D components of a biological neural network visualized in computer generated imagery. II. Macular neural network organization

Computer-assisted reconstructions of small parts of the macular neural network show how the nerve terminals and receptive fields are organized in 3-dimensional space. This biological neural network is anatomically organized for parallel distributed processing of information. Processing appears to be more complex than in computer-based neural networks, because spatiotemporal factors figure into synaptic weighting. Serial reconstruction data show anatomical arrangements which suggest that 1) assemblies of cells analyse and distribute information with inbuilt redundancy, to improve reliability; 2) feedforward/feedback loops provide the capacity for presynaptic modulation of output during processing; 3) constrained randomness in connectivities contributes to adaptability; and 4) local variations in network complexity permit differing analyses of incoming signals to take place simultaneously. The last inference suggests that there may be segregation of information flow to central stations subserving particular functions.

Computer-aided three-dimensional reconstruction of the inner hair cells and their nerve endings in the guinea pig cochlea

The inner hair cells and their nerve endings in the basal and third turns of the guinea pig cochlea were reconstructed three-dimensionally from serial thin sections by means of computer graphics. The inner hair cells showed narrowing below the cuticular plate and gradual increase in size toward the base where the surface was indented by nerve attachments. The sizes of the afferent nerve endings were in the range of 0.9 to 3.2 microns in cross section. Large endings were fewer and were located mainly on the pillar cell side, whereas small endings were numerous and were located on the modiolar side. The number of afferent nerve endings on a single cell in the basal turn averaged 26 and in the third turn, 17. All the afferent fibers were unbranched, most of them innervated a single cell, and 81% of them formed synapses with distinct synaptic bodies in the inner hair cells. A few afferent endings formed membrane specializations with two adjacent inner hair cells but the synaptic body was seen in only one cell. The number of efferent endings, from 0.08 to 2.0 micron in diameter, was about nine in the basal turn and was seven in the third turn. No significant difference was seen between the basal and third turns in cell shape, proportion of afferent to efferent endings, nor in morphology of synapses.

Spiny neurons lacking choline acetyltransferase immunoreactivity are major targets of cholinergic and catecholaminergic terminals in rat striatum

The ultrastructural substrate for functional interactions between intrinsic cholinergic neurons and catecholaminergic afferents to the caudate-putamen nucleus and nucleus accumbens septi (NAS) was investigated immunocytochemically. Single sections of glutaraldehyde-fixed rat brain were processed 1) for the immunoperoxidase labeling of a rat monoclonal antibody against the acetylcholine-synthesizing enzyme choline acetyltransferase (CAT) and 2) for the immunoautoradiographic localization of a rabbit polyclonal antiserum against the catecholamine-synthesizing enzyme tyrosine hydroxylase (TH). The ultrastructural morphology and cellular associations did not significantly differ in the caudate-putamen versus NAS. Immunoperoxidase reaction for CAT versus NAS. Immunoperoxidase reaction for CAT was seen in perikarya, dendrites, and terminals, whereas immunoautoradiography for TH was in terminals. The perikarya and dendrites immunolabeled for CAT were large, sparsely spiny, and postsynaptic mainly to unlabeled axon terminals. Only 2-3% of the CAT-labeled terminals (n = 136) and less than 1% of the TH-labeled terminals (n = 86) were apposed to, or formed synapses with, perikarya or dendrites immunoreactive for CAT. Most unlabeled and all labeled terminals formed symmetric synapses. In the same sample, 18% of the CAT and 16% of the TH-labeled terminals were directly apposed to each other. Unlabeled dendritic shafts received the major (40% for CAT versus 23% for TH) synaptic input from cholinergic terminals, while unlabeled spines received the major (47% for TH versus 23% for CAT) synaptic input from catecholaminergic terminals. Neither the unlabeled dendrites or spines received detectable convergent input from CAT and TH-labeled terminals. Thirteen percent of the CAT-labeled and 14% of TH-labeled terminals were in apposition to unlabeled terminals forming asymmetric, presumably excitatory, synapses with unlabeled dendritic spines. We conclude that in both the caudate-putamen and NAS cholinergic and catecholaminergic terminals 1) form symmetric, most likely inhibitory, synapses primarily with non-cholinergic neurons, 2) differentially synapse on shafts or spines of separate dendrites, and 3) have axonal appositions suggesting the possibility of presynaptic physiological interactions. These results support the hypothesis that the cholinergic-dopaminergic balance in striatal function may be mediated through inhibition of separate sets of spiny projection neurons with opposing excitatory and inhibitory functions.

Ultrastructural morphometric study of efferent nerve terminals on murine bone marrow stromal cells, and the recognition of a novel anatomical unit: the "neuro-reticular complex"

In order to extend our understanding of the role of nerve fibers in the structure and function of bone marrow stroma, we have examined nerve terminals, arterioles, and capillaries in femoral bone marrow tissues of 50 C57BL strain mice, using electron microscopy and morphometric methods. Within the adventitia of arterioles, a particular type of cell, termed periarterial adventitial (PAA) cell, is characterized by a thin veil-like cytoplasm which concentrically surrounds both nerves and arterioles. Nerve fibers containing both unmyelinated and myelinated axons are distributed mainly between the layers of PAA cells, but are found rarely on the sinus walls or within the hematopoietic parenchyma. Quantitatively, the efferent nerve terminals with many synaptic vesicles are distributed mainly beside arterial smooth muscle cells (Type I: 58.8%) or between the layers of PAA cells (Type III: 33.2%), and rarely in hematopoietic parenchyma (Type II: 5.3%) or on sinus walls (Type IV: 2.7%). In the case of Type II-IV nerve terminals, efferent (autonomic) nerves and bone marrow stromal cells which are connected by gap junctions (sinus adventitial reticular cells, intersinusoidal reticular cells, and PAA cells) appear to constitute a potential functional unit for signal conduction. We would like to propose a new term for this anatomical unit in marrow, the "neuro-reticular complex."

[The mechanisms of the reorganization of functional systems in the ontogeny of rats]

Functional systems as well as other mechanisms of regulation of animal behavior (reflexes) have very high adaptive properties. Specific mechanisms of reorganization of the functional systems have been elaborated during ontogenesis to adapt an individual to changing environment.

Telodendrial contact of HRP-filled photoreceptors in the turtle retina: pathways of photoreceptor coupling

Synaptic contacts of photoreceptors in the turtle retina were studied by intracellular injection of horseradish peroxidase (HRP) and electron microscopy. Both cone and rod photoreceptors radiated basal processes (telodendria) from their terminal endings. These telodendria ran laterally in the outer plexiform layer. The telodendria of cones gave rise to many fine branches that penetrated synaptic cavities of several neighboring cones. Tips of these branches terminated near the walls of synaptic cavities. Some of the telodendrial contact formed two types of basal junction: symmetrical and punctate. The distribution of cones that made telodendrial contacts with the HRP-filled cone were quantitatively investigated. Green-sensitive cones (n = 3) made telodendrial contacts with neighboring red- and blue-sensitive cones, blue-sensitive cones (n = 4) with red- and green-sensitive cones, and red-sensitive cones (n = 9) with red- and green-sensitive cones. In contrast to these cone connections, rod telodendria did not penetrate neighboring photoreceptors. Direct synaptic contacts were not found between rods and cones. Our results clarify the variety of cone couplings in turtle retina: the three chromatic classes of cones are selectively coupled by the basal junctions at the ends of telodendrial processes.

Vomeronasal and olfactory nerves of adult and larval bullfrogs: II. Axon terminations and synaptic contacts in the accessory olfactory bulb

The ultrastructure of the accessory olfactory bulb (AOB) of the bullfrog tadpole and adult was examined, and the main difference between tadpole and adult is that the latter is more compact and shows more synapses. Except for vomeronasal (VMN) glomeruli, the AOB is not highly organized, with mitral cell neurons scattered throughout the neuropil. VMN axon terminals form asymmetric synapses with mitral cell dendrites in glomeruli; in VMN axon terminals, dense-cored vesicles are seen along with the more abundant lucent vesicles 40-50 nm in diameter. Counts indicated that more than 90% of the dendro-dendritic synapses between mitral cells and presumed granule cells are of the asymmetrical type, and reciprocal asymmetrical-symmetrical synapses are not common. Lucent vesicles with round or slightly ellipsoidal profiles and less abundant dense-cored vesicles 60-90 nm in diameter are found in pre- and postsynaptic dendrites; sometimes the dense-cored vesicles lie against or near the presynaptic membrane. Microtubules were often seen to be closely associated with pre- and postsynaptic elements of dendro-dendritic synapses. The most characteristic feature of mitral cell bodies, apart from their large size, is an extensive Golgi system that may extend well into their major dendritic extensions. Dense-cored vesicles are associated with Golgi membranes, from which they probably originate. Centrioles are associated with the Golgi system, and some become basal bodies and give rise to cilia in some mitral cells.

Functional organization of ascending and descending connections of the cochlear nucleus of horseshoe bats

The ascending projections of the cochlear nucleus (CN) and the sources of descending inputs to the CN were investigated in horseshoe bats (Rhinolophus rouxi) by tracing the anterograde and retrograde transport of horseradish peroxidase (HRP or WGA-HRP) injected into the CN. The tracer was iontophoretically deposited into physiologically characterized regions of the cochlear nucleus (Feng and Vater, '85). We report the course and termination of pathways arising from the anteroventral (AVCN), posteroventral (PVCN), and dorsal (DCN) cochlear nucleus. The projection fields within the auditory brainstem centers (superior olivary complex [SOC]; lateral lemniscus complex [LLC]; and inferior colliculus [IC]) and their tonotopic organization according to the frequency representations at the injection sites are described. While the projection pattern is generally in accordance with other mammals, several species-characteristic features are noted: i) the lateral superior olive (LSO) receives tonotopically organized input from both the AVCN and PVCN; ii) the CN-projections to medial nuclear groups of the SOC located between the LSO and the medial nucleus of the trapezoid body do not support previously suggested homologies; iii) the ventral nucleus of the LLC can be subdivided into two divisions with distinct input patterns from the AVCN and PVCN, respectively.

High density of zinc-containing and dynorphin B- and substance P-immunoreactive terminals in the marginal division of the rat striatum

A distinct subdivision of the striatum has recently been described which is located at the caudomedial margin of the striatum, surrounding the rostrolateral edge of the globus pallidus. This "marginal division" has an internal organization and an efferent distribution which is distinct from the rest of the striatum. The striatum contains moderately high levels of zinc and the neuropeptides enkephalin, dynorphin and substance P. In the present study we have examined the distribution of histologically detectable zinc and of dynorphin B- and substance P-immunoreactivity in the marginal division of the striatum. Each of these substances was more dense within the confines of the marginal division than in the rest of the striatum. These data provide further evidence that the marginal division is a structurally distinct subdivision of the striatum.

Morphology of presumptive rapidly adapting receptors in the rat bronchus

The present investigation was undertaken in rats to determine whether sensory nerves exist in apposition to the bronchial microvessels which may function as rapidly adapting receptors (RAR). The primary and secondary bronchi on both sides were removed and processed for light and electron microscopy. Nerves were frequently found in relation to venules external to the muscle coat of bronchi. They comprised myelinated axons which ended individually as non-myelinated convoluted terminals enclosed within a loose capsule of attenuated cells. Serial sections showed that these terminals were not related to ganglion cells. Cervical vagal section and injection of HRP-WGA into the nodose ganglion provided corroborative evidence of the sensory nature of these terminals. Vagal section caused degenerative changes in the encapsulated nerve terminals in the bronchial walls and horseradish peroxidase labelling was demonstrable in such terminals. Moreover, immunocytochemical studies demonstrated the presence of calcitonin gene regulated peptide and substance P in these structures. It is suggested that they comprise the RAR. Encapsulated nerve terminals were not found in the epithelial layer, in the submucous coat or in the muscularis of bronchi.

Ultrastructural three-dimensional reconstruction of group III and group IV sensory nerve endings ("free nerve endings") in the knee joint capsule of the cat: evidence for multiple receptive sites

The noncorpuscular endings ("free nerve endings") of thinly myelinated group III and nonmyelinated group IV afferent nerve fibers have been examined in the knee joint capsule of sympathectomized cats by transmission electron microscopy and three-dimensional reconstruction of series of semi- and ultrathin sections. The sensory ending is the most distal part of a group III or IV nerve fiber that consists only of the sensory axon and associated Schwann cells but lacks a myelin sheath and is not surrounded by perineurium. The sensory axon divides into several branches and forms a terminal tree. The branches run either as single fibers or within small Remak bundles in parallel to sensory axons of other endings; they spread along vessel walls and also extend into dense connective tissue. Each sensory axon consists of a series of spindle-shaped thick segments ("beads") connected by waist-like thin segments. Thus all axons of sensory endings have a string-of-beads appearance, which resembles that of efferent sympathetic nerve fibers. The beads of the sensory axon and the end bulb at its tip show the same ultrastructural features which are characteristic of receptive sites: an accumulation of mitochondria and glycogen particles and various vesicles in the axoplasm and "bare" areas of axolemma that are not covered by Schwann cell processes. Group III and group IV sensory endings differ in the length of their branches (up to 200 microM in group III vs. more than 300 microM in group IV), number of beads per 100 microM axon length (about seven vs. nine or ten), mean diameter of axons (0.9-1.5 microM vs. 0.3-0.6 microM), and the presence of a neurofilament core consisting of bundles of parallel microfilaments only in group III. In conclusion, we propose that the sensory part of noncorpuscular "free nerve endings" is formed by the entire terminal tree of group III or group IV nerve fibers and that the beads in the course of the sensory axon represent multiple receptive sites.

Orthogonal arrays of intramembranous particles in the Müller cell and astrocyte endfoot membrane of rabbit retina. Postnatal development and adulthood

The freeze-fracture technique was applied to the retina of early postnatal and adult rabbits to investigate the distribution and density of orthogonal arrays of intramembrane particles (OAP) within the vitread endfoot membranes. In adult animals, two distinct types of endfoot membranes were observed within the central myelinated retina but not in the retinal periphery. One type of endfoot membranes contained low density of individual 'background' particles, and a more or less stripe-like pattern of OAP; this type was found only within the myelinated centre and is concluded to represent membranes of retinal astrocytes. The other type of endfoot membranes was rather tightly packed with individual 'background' particles, and contained OAP which formed rows only at the margins of footplates; this kind of membrane was found throughout the whole retina, and represents Müller cell endfeet. The density of OAP in both types of endfoot membranes was higher within the central myelinated retina than in the Müller cell endfeet of the retinal periphery. In early postnatal retinae, a discrimination between the two types of endfeet was impossible. At the day of birth, only very few OAP were observed, and the majority of footplates were free of OAP. Within the next 10 days, both density and size of OAP were found to increase but fail to reach adult levels. Quantitative data are presented with the hope of providing a basis for future correlation with functional maturation of rabbit retinal glia.