Fine structure of long-term changes in the cochlear nucleus after acoustic overstimulation: chronic degeneration and new growth of synaptic endings

The companion study showed that acoustic overstimulation of adult chinchillas, with a noise level sufficient to damage the cochlea, led to cytological changes and degeneration of synaptic endings in the cochlear nucleus within 1-16 weeks. In the present study, the same stimulus was used to study the long-term effects on the fine structure of synaptic endings in the cochlear nucleus. For periods of 6 and 8 months after a single exposure to a damaging noise level, there ensued a chronic, continuing process of neurodegeneration involving excitatory and inhibitory synaptic endings. Electron microscopic observations demonstrated freshly occurring degeneration even as late as 8 months. Degeneration was widespread in the neuropil and included the synapses on the globular bushy cell, which forms part of the main ascending auditory pathway. Neurodegeneration was accompanied by newly formed synaptic endings, which repopulated some of the sites vacated previously by axosomatic endings on globular bushy cells. Many of these synaptic endings must arise from central interneurons. The findings suggest that overstimulation can induce a self-sustaining condition of progressive neurodegeneration accompanied by a new growth of synaptic endings. Noise-induced hearing loss thus may progress as a neurodegenerative disease with the capacity for synaptic reorganization within the cochlear nucleus.     

Synaptophysin in the cochlear nucleus following acoustic trauma

Chinchillas are notable for a low-frequency hearing range similar to that of humans and a marked sensitivity to loud noise. A single noise exposure that produces cochlear damage may lead to progressive loss of synaptic endings in the cochlear nucleus, followed by new axonal growth. As an index of synaptic regulation during such changes, we have examined the expression of a synaptic vesicle protein, synaptophysin, in the cochlear nucleus following a damaging acoustic stimulus in adult chinchillas. With one ear protected by a plug, following a 3-h exposure to an octave-band noise of 108 dB sound pressure level, centered at 4 kHz, the unprotected cochlea and the cochlear nuclei exhibited degeneration of hair cells and axons over periods of 7, 14, 30, 90, and 150 days. Axonal degeneration, as revealed by a silver degeneration method, was heavy ipsilateral to the cochlear damage, but sparse degeneration also appeared on the contralateral, unexposed side. Synaptophysin immunostaining underwent a major, bilateral decline in the anteroventral and posteroventral cochlear nuclei, interrupted at intervening periods by transient increases in the numbers of stained structures. A distinction in staining between large perisomatic structures and smaller puncta in the neuropil and between the dorsal and the ventral zones of the ventral cochlear nuclei revealed some variations in the response and degree of recovery of synaptophysin staining. These findings could best be explained by degeneration of synaptic endings followed by new growth of terminals and by regulatory changes in the levels of synaptophysin expression and synaptic vesicle accumulation over time.     

Quantitative study of degeneration and new growth of axons and synaptic endings in the chinchilla cochlear nucleus after acoustic overstimulation

To determine if acoustic overstimulation altered synaptic connections in the cochlear nucleus, anesthetized adult chinchillas, with one ear protected by a silicone plug, were exposed for 3 hr to a 108-dB octave-band noise, centered at 4 kHz, and allowed to survive for periods up to 32 weeks. This exposure led to cochlear damage in the unprotected ear, mainly in the basal regions of the organ of Corti. The anterior part of the ipsilateral posteroventral cochlear nucleus consistently contained a band of degenerating axons and terminals, in which electron microscopic analysis revealed substantial losses of axons and synaptic terminals with excitatory and inhibitory cytology. The losses were significant after 1 week's survival and progressed for 16-24 weeks after exposure. By 24-32 weeks, a new growth of these structures produced a resurgence in the number of axons and terminals. The net number of excitatory endings fully recovered, but the quantity with inhibitory cytology was only partially recouped. Neuronal somata lost both excitatory and inhibitory endings at first and later recovered a full complement of excitatory but not inhibitory terminals. Dendrites suffered a net loss of both excitatory and inhibitory endings. Excitatory and inhibitory terminals with unidentified postsynaptic targets in the neuropil declined, then increased in number, with excitatory terminals exhibiting a greater recovery. These findings are consistent with a loss and regrowth of synaptic endings and with a reorganization of synaptic connections that favors excitation.     

Transneuronal changes of synaptic endings and nuclear chromatin in the trapezoid body following cochlear ablations in cats

This study demonstrates long-lasting structural changes in highly specific synaptic endings, the calyces of Held, and in the principal cells, contacted by calyces, in the medial trapezoid nucleus following acoustic deafferentation of adult cats. The normal structure of the principal cell and its afferent axosomatic endings, including the calyx and other, smaller endings, was defined in rapid Golgi impregnations and electron micrographs. Each calyciferous axon, arising from the contralateral cochlear nucleus, forms a calyx, about 35 μm in diameter, around only one principal cell body; each principal cell receives only one calyx. In electron micrographs a calycine profile typically contains a central core of neurofilaments, surrounded by mitochondria; spherical vesicles gather at multiple, asymmetric synaptic complexes. Fifteen and 30 days after unilateral labyrinthectomy the contralateral calyces showed neurofilamentous hyperplasia; mitochondria and the now enlarged synaptic vesicles decreased in number. After 30 days the contralateral principal neurons showed increased condensation of nuclear chromatin. All of these changes diminished after 56 days and were gone by seven months, when the principal cell body had shrunk by 30%. The calyx, which exhibits strongly excitatory synaptic transmission spontaneously and during acoustic stimulation, could mediate significant trophic effects. Such effects are no doubt reflected in the extensive transneuronal changes after interruption of cochlear input. These changes must involve pre- and post-synaptic alterations of protein metabolism, control of which may be linked to synaptic transmission.     

Projections of the second cervical dorsal root ganglion to the cochlear nucleus in rats

Physiological, anatomical, and clinical data have demonstrated interactions between somatosensory and auditory brainstem structures. Spinal nerve projections influence auditory responses, although the nature of the pathway(s) is not known. To address this issue, we injected biotinylated dextran amine into the cochlear nucleus or dorsal root ganglion (DRG) at the second cervical segment (C2). Cochlear nucleus injections retrogradely labeled small ganglion cells in C2 DRG. C2 DRG injections produced anterograde labeling in the external cuneate nucleus, cuneate nucleus, nucleus X, central cervical nucleus, dorsal horn of upper cervical spinal segments, and cochlear nucleus. The terminal field in the cochlear nucleus was concentrated in the subpeduncular corner and lamina of the granule cell domain, where endings of various size and shapes appeared. Examination under an electron microscope revealed that the C2 DRG terminals contained numerous round synaptic vesicles and formed asymmetric synapses, implying depolarizing influences on the target cell. Labeled endings synapsed with the stalk of the primary dendrite of unipolar brush cells, distal dendrites of presumptive granule cells, and endings containing pleomorphic synaptic vesicles. These primary somatosensory projections contribute to circuits that are hypothesized to mediate integrative functions of hearing.     

Noise trauma alters D-[3H]aspartate release and AMPA binding in chinchilla cochlear nucleus

Exposure of adults to loud noise can overstimulate the auditory system, damage the cochlea, and destroy cochlear nerve axons and their synaptic endings in the brain. Cochlear nerve loss probably results from the death of cochlear inner hair cells (IHC). Additional degeneration in the cochlear nucleus (CN) is hypothesized to stem from overstimulation of the system, which may produce excitotoxicity. This study tested these predictions by exposing one ear of anesthetized adult chinchillas to a loud noise, which damaged the ipsilateral cochlea and induced degeneration in the glutamatergic cochlear nerve. During the first postexposure week, before cochlear nerve axons degenerated, glutamatergic synaptic release in the ipsilateral CN was elevated and uptake was depressed, consistent with hyperactivity of glutamatergic transmission and perhaps with the operation of an excitotoxic mechanism. By 14 days, when cochlear nerve fibers degenerated, glutamatergic synaptic release and uptake in the CN became deficient. By 90 days, a resurgence of transmitter release and an elevation of AMPA receptor binding suggested transmission upregulation through plasticity that resembled changes after mechanical cochlear damage. These changes may contribute to tinnitus and other pathologic symptoms that precede and accompany hearing loss. In contrast, the other ear, protected with a silicone plug during the noise exposure, exhibited virtually no damage in the cochlea or the cochlear nerve. Altered glutamatergic release and AMPA receptor binding activity in the CN suggested upregulatory plasticity driven by signals emanating from the CN on the noise-exposed side.     

Degeneration and phagocytosis of synaptic endings and axons in the medial trapezoid nucleus of the cat

This study deals with the fine structure of the degenerative changes in the axonal calyces of the medial trapezoid nucleus after destruction of their cell bodies of origin in the contralateral cochlear nucleus. Two to four days after such lesions the main calycine processes which normally contain a core of neurofilaments, show a marked hyperplasia of neurofilaments, shrinkage, decrease in number of microtubules and mitochondria, swelling and decrease in number of synaptic vesicles, and the appearance of vesicular debris and coated vesicles. After seven days all of the calyces have degenerated. They are replaced by extracellular accumulations of neurofilaments, surrounded by phagocytic processes of proliferating astroglia and microglia. In contrast, the calycine appendages exhibit a dense mode of degeneration. Thus the different kinds of endings, arising from the very same fibers and synapsing on the very same cell bodies, exhibit two entirely different modes of degeneration. There is a correlation between the normal cytological features of the endings and their modes of degeneration. The preterminal calycine axons undergo filamentous hyperplasia in early degeneration. The observations indicate that both microglia and astroglia may participate in phagocytosis of the preterminal fibers and their endings and that astrocytes undergo mitosis. The microglia in electron micrographs correspond to the classical microglial cells that appear in perivascular locations in Golgi preparations. The disintegration of the calyces is accompanied by mutual invaginations of thin axonal and glial processes, followed by the disappearance of the axolemma. Extracellular break-up appears to be a regular feature of this process, which may involve the intercellular transfer of soluble breakdown products by calycine and glial vesicles and uptake by tubular elements of the smooth endoplasmic reticulum in the phagocytes. Incisures of Schmidt-Lanterman occur in the large calyciferous fibers; these fibers are often invaded by phagocytes before the myelin sheath degenerates.     

New Growth of Axons in the Cochlear Nucleus of Adult Chinchillas after Acoustic Trauma

This study determined the effect of acoustic overstimulation of the adult cochlea on axons in the cochlear nucleus. Chinchillas were exposed to an octave-band noise centered at 4 kHz at 108 dB sound pressure level for 1.75 h. One chinchilla was never exposed to the noise, and several others had one ear protected by an ear plug or prior removal of the malleus and incus. Exposure of unprotected ears caused loss of inner and outer hair cells and myelinated nerve fibers, mostly in the basal half of the cochlea. Cochlear nerve fiber degeneration, ipsilateral to the exposed ears, was traced to regions of the cochlear nucleus representing the damaged parts of the cochlea. In silver impregnations of a deafferented zone in the posteroventral cochlear nucleus, the concentration of axons decreased by 43% after 1 month and by 54% after 2 months. However, by 8 months, the concentration of thinner axons, with diameters of less than 0.46 μm, increased by 46–90% over that at 2 months. The concentration of axons with larger diameters did not change. Between 2 and 8 months small axonal endings appeared next to neuronal cell bodies. This later increase of thinner axons and endings is consistent with a reactive growth of new axons of relatively small diameter. The emergence of small perisomatic boutons suggests that the new axons formed synaptic endings, which might contribute to an abnormal reorganization of the central auditory system and to the pathological changes that accompany acoustic overstimulation.     

An electron microscopic study of synaptic organization in the medial superior olive of normal and experimental chinchillas

The medial superior olive (MSO) was studied in normal animals to determine the types of synaptic endings and their distribution over the surface of MSO neurons. Unilateral lesions were made in the anteroventral cochlear nucleus (AVCN) of experimental animals to determine the source of at least one synaptic type in the MSO. The surfaces of MSO neurons in normal animals were studded with three distinct types of synaptic endings distinguished mainly by the size of their synaptic vesicles. There were endings with large vesicles, 510 Å in mean diameter; endings with small vesicles, 380 Å; and endings with vesicles intermediate in size. 435 Å. The large vesicle ending typically was greater than 2 μm in maximum diameter. It appeared as the termination of a myelinated axon or as a swollen portion of a node and made multiple asymmetrical synapses. Large vesicle endings occurred exclusively on dendrites where they formed 85% of the synaptic endings. Small vesicle endings typically were less than 2 μm in diameter. They appeared as the termination of a fine unmyelinated axon and made only one symmetrical synapse. Small vesicle boutons occurred infrequently over the entire neuronal surface. Intermediate vesicle synaptic endings were similar to large vesicle endings except that they were present only on the cell body, axon hillock, and proximal portions of the dendrites where they formed most of the synapses. In AVCN lesioned animals degenerating myelinated axons and large vesicle synaptic endings were distributed to the lateral dendrites of the ipsilateral MSO and medial dendrites of the contralateral one. In addition, a few degenerating axons and large vesicle endings were found among the ipsilateral medial dendrites. The changes in the degenerating endings were characterized by an early proliferation of neurofilaments and swelling of the endings followed by collapse of the endings and increase in electron density, disappearance of filaments and synaptic vesicles, and phagocytosis of the degenerated endings by reactive glial cells. No degenerative changes were observed in the small and intermediate vesicle endings. The results of this study indicate that the more numerous large vesicle endings presynaptic to the MSO dendrites are the axon terminals of neurons in the AVCN. The persistence after lesions of the small and intermediate vesicle endings suggests that they arise from as yet unidentified sources.     

Aspartic acid and glutamic acid levels in the cochlear nucleus after auditory nerve lesion

Aspartic acid, glutamic acid and alanine were measured in the cochlear nucleus after lesioning the auditory nerve by cochlear ablation. Ultrastructural analysis of the cochlear nucleus showed that most primary auditory terminals were degenerating one day after cochlear ablation; the terminals were enlarged and the number of synaptic vesicles was reduced. Primary auditory terminals were virtually gone three days after cochlear ablation. Aspartic acid decreased after cochlear ablation in parallel with the morphological degeneration of the primary auditory terminals. The level of total aspartic acid in the cochlear nucleus had decreased more than 8% one day after cochlear ablation and more than 30% after two days, and remained at this level up to 28 days. Glutamic acid also decreased in the cochlear nucleus after cochlear ablation but not in parallel with the morphological degeneration of the primary auditory terminals. Following a slight increase one day after cochlear ablation, total glutamic acid decreased about 10% after two days and continued to decrease slowly through to day 28. Alanine dropped slowly after cochlear ablation and not in parallel with the degeneration of the primary terminals. Levels of other amino acids measured were unchanged or had increased two days after cochlear ablation. Aspartic acid and glutamic acid did not decrease in the superficial layers of the dorsal cochlear nucleus, an area receiving little or no primary innervation.     

Plasticity of synaptic endings in the cochlear nucleus following noise-induced hearing loss is facilitated in the adult FGF2 overexpressor mouse

In adult mammals a single exposure to loud noise can damage cochlear hair cells and initiate subsequent episodes of degeneration of axonal endings in the cochlear nucleus (CN). Possible mechanisms are loss of trophic support and/or excitotoxicity. Fibroblast growth factor 2 (FGF2), important for development, might be involved in either mechanism. To test this hypothesis, we noise-exposed FGF2 overexpressor mice and observed the effects on synaptic endings by immunolabelling for SV2, a synaptic vesicle protein, at 1, 2, 4, and 8 weeks after noise exposure. SV2 staining was observed in two major locations; perisomatic, representing axo-somatic terminals, and neuropil, representing axo-dendritic terminals. The wildtype (WT) lost both perisomatic and neuropil clusters with an intervening period of modest recovery for the perisomatic. In contrast, in the overexpressor, the perisomatic clusters remained unchanged after intervening periods of increase. The neuropil clusters underwent a period of initial decline, followed by a transient recovery and ultimate decline. Changes in SV2 immunostaining correlated with changes in vesicular glutamate and GABA transporters at synapses and, in the overexpressor, with staining changes for FGF2 and FGF receptor 1. These molecules may contribute to the synaptic reorganization after noise damage; they may protect and/or aid recovery of synapses after overstimulation.     

Differential distribution of synaptic endings containing glutamate, glycine, and GABA in the rat dorsal cochlear nucleus

The dorsal cochlear nucleus (DCN) integrates the synaptic information depending on the organization of the excitatory and inhibitory connections. This study provides, qualitatively and quantitatively, analyses of the organization and distribution of excitatory and inhibitory input on projection neurons (fusiform cells), and inhibitory interneurons (vertical and cartwheel cells) in the DCN, using a combination of high-resolution ultrastructural techniques together with postembedding immunogold labeling. The combination of ultrastructural morphometry together with immunogold labeling enables the identification and quantification of four major synaptic inputs according to their neurotransmitter content. Only one category of synaptic ending was immunoreactive for glutamate and three for glycine and/or gamma-aminobutyric-acid (GABA). Among those, nine subtypes of synaptic endings were identified. These differed in their ultrastructural characteristics and distribution in the nucleus and on three cell types analyzed. Four of the subtypes were immunoreactive for glutamate and contained round synaptic vesicles, whereas five were immunoreactive for glycine and/or GABA and contained flattened or pleomorphic synaptic vesicles. The analysis of the distribution of the nine synaptic endings on the cell types revealed that eight distributed on fusiform cells, six on vertical cells and five on cartwheel cells. In addition, postembedding immunogold labeling of the glycine receptor alpha1 subunit showed that it was present at postsynaptic membranes in apposition to synaptic endings containing flattened or pleomorphic synaptic vesicles and immunoreactive for glycine and/or GABA on the three cells analyzed. This information is valuable to our understanding of the response properties of DCN neurons.     

Chemical anatomy of excitatory endings in the dorsal cochlear nucleus of the rat: Differential synaptic distribution of aspartate aminotransferase,glutamate, and vesicular zinc

In order to identify cytochemical traits relevant to understanding excitatory neurotransmission in brainstem auditory nuclei, we have analyzed in the dorsal cochlear nucleus the synaptic distribution of aspartate aminotransferase, glutamate, and vesicular zinc, three molecules probably involved in different steps of excitatory glutamatergic signaling. High levels of glutamate immunolabeling were found in three classes of synaptic endings in the dorsal cochlear nucleus, as determined by quantitation of immunogold labeling. The first type included auditory nerve endings, the second were granule cell endings in the molecular layer, and the third very large endings, better described as “mossy.” This finding points to a neurotransmitter role for glutamate in at least three synaptic populations in the dorsal cochlear nucleus. The same three types of endings enriched in glutamate immunoreactivity also contained histochemically detectable levels of aspartate aminotransferase activity, suggesting that this enzyme may be involved in the synaptic handling of glutamate in excitatory endings in the dorsal cochlear nucleus. There was also extrasynaptic localization of the enzyme. Zinc ions were localized exclusively in granule cell endings, as determined by a Danscher-selenite method, suggesting that this ion is involved in the operation of granule cell synapses in the dorsal cochlear nucleus. J. Comp. Neurol. 399:341–358, 1998. © 1998 Wiley-Liss, Inc.     

Synaptophysin immunoreactivity in the cochlear nucleus after unilateral cochlear or ossicular removal

This study determined if unilateral cochlear removal in adult guinea pigs led to synaptic loss followed by synaptogenesis in the cochlear nucleus (CN) and if unilateral middle ear ossicle removal led to synaptic loss in the CN. Synaptic endings were identified immunohistochemically, using a monoclonal antibody to synaptophysin. Immunolabeling was quantified densitometrically in the CN 4–161 days after cochlear removal and 161 days after ossicle removal. Fiber degeneration was visualized with the Nauta-Rasmussen silver method. Tissue shrinkage was measured from drawings of CN sections. Compared to the contralateral side, immunolabeling density ipsilaterally was reduced by 4 days in the anterior division of the anteroventral CN (a-AVCN) and by 7 days in the anterior part of the posteroventral CN (a-PVCN). At 7 days, preterminal fiber degeneration was abundant in both areas. These findings were consistent with the loss of cochlear nerve endings and fibers. At later times, immunolabeling density recovered. In the a-AVCN, tissue shrinkage explained approximately half the recovery of staining density; the rest was attributed to synaptogenesis. In the a-PVCN, the entire recovery was attributed to tissue shrinkage. In the polymorphic layer of the dorsal CN, immunostaining density increased transiently at 4 days, while at 7 days preterminal fiber degeneration was abundant. A net loss of synaptic endings was not detected immunohistochemically. The increased immunostaining density may reflect a transient growth of immature processes or presynaptic endings. Ossicle removal produced a deficit in immunolabeling density only in the ipsilateral a-PVCN, without fiber degeneration, suggesting a loss of presynaptic endings or of synaptophysin expression. Synapse 25:243–257, 1997. © 1997 Wiley-Liss, Inc.     

Enlargement of synaptic vesicles as an early sign of terminal degneration in the rat caudate nucleus

The enlargement of synaptic vesicles in degenerating terminals which has recently been demonstrated in the pigeon retino-tectal fibers as an early sign of secondary degeneration, is confirmed in the rat cortico-caudate system. Enlarged synaptic vesicles appear already five hours postoperatively in endings which subsequently undergo the classical changes of Wallerian degeneration. Three categories of terminals, S_S⁻, S_L⁻ and F-terminals, are defined on the basis of shape and size of synaptic vesicles in the normal rat caudate nucleus. Only the first category is involved after cortical ablation, while the others remain unchanged.     

Projections to the inferior colliculus from the anteroventral cochlear nucleus in the cat: possible substrates for binaural interaction

The projections to the inferior colliculus of the cat are shown in autoradiographs after injections of 3H-amino acids into the anteroventral cochlear nucleus and anterograde axonal transport. Labeled bands of axons are seen in the central nucleus of the inferior colliculus, parallel to the fibrodendritic laminae, and in layers 3 and 4 of the dorsal cortex. A bilateral projection to the lateral, low-frequency part of the inferior colliculus is observed. In contrast, the more ventromedial, mid- and high-frequency parts receive only a contralateral input. The projections from the cochlear nucleus to both the contralateral midbrain and bilaterally to the superior olivary complex appear to be tonotopically organized. After HRP injections in the inferior colliculus, small numbers of stellate neurons are labeled in the lateral and ventral low-frequency parts of the anteroventral cochlear nucleus on the ipsilateral side. EM autoradiographs show labeled axonal endings from both sides of the anteroventral cochlear nuclei are present in the same proportion in pars lateralis. Axonal endings from either cochlear nucleus have small, round synaptic vesicles and make asymmetric synaptic contacts on dendrites. Axons from the contralateral side also make axosomatic contacts on large disc-shaped or stellate cells. Neurons from the ipsilateral anteroventral cochlear nucleus apparently make more synaptic endings per cell as compared to neurons from the contralateral side. Together, bilateral inputs from the anteroventral cochlear nucleus can account for a third of the endings with round synaptic vesicles in pars lateralis of the central nucleus. Morphological similarities among the ascending inputs to the inferior colliculus are discussed. Both direct circuits from the cochlear nucleus to the inferior colliculus and indirect circuits via the superior olivary complex or lateral lemniscus may display banding patterns, nucleotopic organization, or differential synaptic organization. The direct inputs from the anteroventral cochlear nucleus to the colliculus may influence binaural interactions which occur in the superior olivary complex. In addition, direct inputs may create new binaural responses in the inferior colliculus that are independent of lower centers.     

Synaptic organization of globular bushy cells in the ventral cochlear nucleus of the cat: a quantitative study.

The synaptic organization of globular bushy cells of the anteroventral cochlear nucleus was quantitatively analyzed in order to understand better their functional attributes. A method was devised to estimate the concentrations and relative proportions of synapses on the entire postsynaptic surface of Golgi-impregnated neurons, by sampling with limited series of sections for electron microscopy. This provided a characteristic synaptic profile which was homogeneous for the population measured. The total concentration of synaptic endings decreases with distance from the soma. The cochlear, presumably glutamatergic and excitatory, endings with large spherical vesicles (LS) account for most of this decrease. Of the noncochlear inputs, the putative glycinergic endings with flattened vesicles (FL) decrease slightly, and the presumed GABAergic terminals with pleomorphic vesicles (PL) maintain a relatively constant concentration, while endings with small spherical vesicles (SS) increase on the distal dendrites. LS endings have the largest proportion of synapses near the soma, while FL synapses maintain a constant proportion in all cell regions, and PL and SS proportions increase on higher-order dendrites. Excitatory and inhibitory synapses have significant inputs to the axon hillock and initial segment, as well as to the distal dendrites, where dual synapses may provide a way to sample the activity of surrounding neurons. These features must be considered in explanations of physiological properties, such as the synaptic security, level of spontaneous activity, and well-timed, rapid onset responses, as well as their potential for normalizing and synchronizing an important inhibitory pathway involved in binaural signal processing. Synaptic profile analysis should be useful for experimental studies and for developing realistic computational models.     

The organization of the posterior ventral cochlear nucleus in the rat

The ventral cochlear nucleus was examined in 31 rats' brains prepared according to the protargol method of Bodian. The following regions were delimited on the basis of synaptic, cellular and axonal criteria. Region II, which occupies the central part of the nucleus, consists principally of cells (type g)which receive modified bulbs of Held from the acoustic nerve and which send large axons to the trapezoid body. The cells were graded in size, the smallest (high frequency) being located dorsally and the larges (low frequency) being located ventrally. Associated with region II are the cells (type b) of the acoustic nerve nucleus. These cells receive boutons from the acoustic nerve and send very large axons to the trapezoid body. Region IV is located in the posterior part of the ventral cochlear nucleus and is composed of large multipolar cells (type k). The dendrites of these cells are specifically organized with respect to the fibers of the acoustic nerve. Synaptic endings, from the descending branch of the acoustic nerve, consist of boutons on cell body and dendrites. The axons of these cells compose the stria of Held. Region V is located in the posterior part of the ventral cochlear nucleus and appeared to have only intrinsic connections. All regions received synaptic endings in addition to those which arose from the acoustic nerve.     

Time course of ultrastructural changes and immunoelectron microscopic localization of neurocalcin in motor endplates of the lumbrical muscles of rats given a single administration of 2,5-di(tert-butyl)-1,4-hydroquinone

A time-course study of ultrastructural changes and immunoelectron microscopic localization of neurocalcin was performed on motor endplates of the lumbrical muscles of female Wistar rats given a single oral administration of 2,5-di(tert-butyl)-1,4-hydroquinone (DTBHQ) at a dose of 120 mg/kg. Toxic signs such as salivation and muscle weakness of the hind legs appeared from 3 h after DTBHQ administration. No remarkable macroscopic or light microscopic changes were noted in the lumbrical muscles of the treated rats. At the ultrastructural level, neurotoxicity characterized by a decreases or loss of synaptic vesicles and mitochondria was observed after 24 h and at the 1-week time point, nerve endings had disappeared in some of the motor endplates, while many neurite nerve endings suggestive of early stage regeneration were apparent. After 6 weeks, newly formed reinnervated endplates were observed. Immunoelectron microscopically, the synaptic vesicle membranes were heavily labeled for neurocalcin in the control rats, but not at 24 h after DTBHQ treatment. Synaptic vesicle membranes in the DTBHQ group were weakly labeled at 1 week, but strongly at 6 weeks. The results strongly suggest that DTBHQ targets the motor endplates in the rat lumbrical muscles, causing depletion of neurocalcin in the synaptic vesicles followed by their loss. Received: 8 February 1999 / Revised, accepted: 20 June 1999     

Projections from auditory cortex to the cochlear nucleus in rats: Synapses on granule cell dendrites

Previous work has demonstrated that layer V pyramidal cells of primary auditory cortex project directly to the cochlear nucleus. The postsynaptic targets of these centrifugal projections, however, are not known. For the present study, biotinylated dextran amine, an anterograde tracer, was injected into the auditory cortex of rats, and labeled terminals were examined with light and electron microscopy. Labeled corticobulbar axons and terminals in the cochlear nucleus are found almost exclusively in the granule cell domain, and the terminals appear as boutons (1–2 μm in diameter) or as small mossy fiber endings (2–5 μm in diameter). These cortical endings contain round synaptic vesicles and form asymmetric synapses on hairy dendritic profiles, from which thin (0.1 μm in diameter), nonsynaptic “hairs” protrude deep into the labeled endings. These postsynaptic dendrites, which are typical of granule cells, surround and receive synapses from large, unlabeled mossy fiber endings containing round synaptic vesicles and are also postsynaptic to unlabeled axon terminals containing pleomorphic synaptic vesicles. No labeled fibers were observed synapsing on profiles that did not fit the characteristics of granule cell dendrites. We describe a circuit in the auditory system by which ascending information in the cochlear nucleus can be modified directly by descending cortical influences. © 1996 Wiley-Liss, Inc.