Presenilin-1 is expressed in neural progenitor cells in the hippocampus of adult mice.

The functions of the presenilin-1 (PS-1) protein remain largely unknown. In adult brain PS-1 is expressed principally in neurons. However during development PS-1 is expressed more widely including in embryonic neural progenitors. To determine if PS-1 is expressed in neural progenitors in adult hippocampus we used bromodeoxyuridine (BrdU) labeling combined with immunostaining for BrdU, PS-1 and markers of neuronal or glial differentiation. Most BrdU labeled cells also expressed PS-1 at a time when few BrdU labeled cells expressed the early neuronal markers beta-III tubulin or TOAD-64 and none expressed mature neuronal (NeuN or calbindin) or astrocytic (GFAP) markers. Cells expressing PS-1 and the neural progenitor marker nestin were also found. Thus PS-1 is expressed in neural progenitor cells in adult hippocampus implying its possible role in neurogenesis in adult brain.     

Increased neurogenesis in brains of scrapie-infected mice

Persistent neurogenesis occurs in the adult brain throughout the life of all mammals. Recent studies have shown that neurogenesis was increased in adult gerbil and rat brains after ischemia. Neurogenesis has not been examined during neurodegenerative diseases such as scrapie. To investigate the regeneration of neurons after scrapie-infection, we infused 5-bromo-2'-deoxyuridine (BrdU), a DNA replication indicator, into both control and scrapie-infected mice. Mice were sacrificed at 150 days post-infection, i.e., at the start of clinical disease and a time when PrP(Sc) was readily detected in brain by both immunostaining and Western blot. We investigated expression of BrdU in each region of brain and observed cellular localization of BrdU using various cell markers such as neuronal nuclear (NeuN), microtubule-associated protein 2 (MAP2) and glial fibrillary acidic protein (GFAP). Immunohistochemically, BrdU-labeled cells were observed in the striatum, hippocampus, and brain stem of scrapie-infected brains. BrdU-labeled cells were much more prevalent in the hippocampus of scrapie-infected mice compared to hippocampus of control brains. In scrapie mice, there was more staining in hippocampus than in other brain regions. We also found that BrdU-positive cells colocalized with the neuronal markers NeuN and MAP2, whereas BrdU staining was not merged with GFAP, an astrocytic marker. Taken together, our results suggest that scrapie-infection induces region-specific increases in neuron regeneration.     

Neurogenesis in olfactory bulb identified by retroviral labeling in normal and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine-treated adult mice

Neurogenesis occurs during development and in the normal adult brain. Recent studies identified areas exhibiting postlesional selective neurogenesis and neuronal repair. In the olfactory bulb (OB), one of the most studied regions of the brain for neurogenesis, seizures and strong odor exposure are known to enhance neurogenesis. Here, we report enhanced neurogenesis in OB after dopaminergic neuronal loss induced by 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), a selective toxin for dopaminergic neurons. The neurogenesis has been previously confirmed mainly by the uptake of 5-bromodeoxyuridine (BrdU), a marker of proliferating cells, but methodological problems related to BrdU labeling might result in inaccurate findings with respect to specificity, toxicity and incorporation into normal/lesioned brain. For a better identification of neurogenesis, we used a retroviral vector. First, we investigated the population dynamics of newly formed neurons in different regions of OB including the glomerular layer, the most superficial layer of OB. Quantification of neurogenesis in OB revealed by our retroviral vector was substantially similar to that by BrdU-based method. One week after MPTP application and dopaminergic neuronal loss in OB, neurogenesis of dopaminergic neurons in OB increased by three-fold, but no such process was noted in non-dopaminergic neurons. Our results indicate selective dopaminergic neurogenesis in OB in response to neuronal damage/loss.     

In vivo neurogenesis in the dorsal vagal complex of the adult rat brainstem

The dorsal vagal complex (DVC) encompasses the nucleus tractus solitarii (NTS), the dorsal motor nucleus of the vagus nerve (DMX) and the area postrema (AP), that altogether provide the major integrative center for the mammalian autonomic nervous system. The adult rat DVC has been reported to contain afferent-dependent concentration of the plasticity-promoting polysialylated form of neural cell adhesion molecule [J Neurosci 21 (2001) 4721; Eur J Neurosci 14 (2001) 1194]. This prompted us to assess the occurrence of neurogenesis in the DVC of adult rats. Cumulative in vivo labeling of cell proliferation with i.p. bromodeoxyuridine (BrdU) injections was combined with phenotypic markers and confocal microscopy on serial brainstem sections throughout the DVC extent. In basal condition, sparse BrdU+ nuclei were selectively detected in the DVC according to a discrete and reproducible pattern. Some of them were found to colocalize with the neuronal markers doublecortin, HuC/D, or neuronal-specific antigen (NeuN), demonstrating that neurogenesis does occur within the DVC of adult rat. In the NTS, 10% of the BrdU+ nuclei were also NeuN+. A comparable proportion of astrogliogenesis was found in the DVC. Nestin immunohistochemistry yielded a highly specific labeling pattern at the border between AP and NTS. These data may relate to the neural stem cells that have been reported in the floor of the IVth ventricle [J Neurosci 16 (1996) 7599]. In order to assess a possible modulation of neurogenesis by afferent input in vivo, unilateral vagotomy was performed prior to cumulative BrdU treatment. Such DVC deafferentation triggered a large increase of BrdU incorporation in the ipsilateral DVC, which was associated with microglial proliferation in the DMX and with increased genesis of neurons and astrocytes in the NTS. These findings establish DVC as a novel model of adult neurogenesis that is reactive to deafferentation.     

Ischemia induces cell proliferation and neurogenesis in the gerbil hippocampus in response to neuronal death

We studied hippocampal cellular proliferation and neurogenesis processes in a model of transient global cerebral ischemia in gerbils by labelling dividing cells with 5'-Bromo-2'-deoxyuridine (BrdU). Surrounding the region of selective neuronal death (CA1 pyramidal layer of the hippocampus), an important increase in reactive astrocytes and BrdU-labelled cells was detected 5 days after ischemia. A similar result was found in the dentate gyrus (DG) 12 days after ischemia. The differentiation of the BrdU+ cells was investigated 28 days after BrdU administration by analyzing the morphology, anatomic localization and cell phenotype by triple fluorescent labelling (BrdU, adult neural marker NeuN and DNA marker TOPRO-3) using confocal laser-scanning microscopy. This analysis showed increased neurogenesis in the DG in case of ischemia and triple positive labelling in some newborn cells in CA1. Seven brain hemispheres from gerbils subjected to ischemia did not develop CA1 neuronal death; hippocampus from these hemispheres did not show any of the above mentioned findings. Our results indicate that ischemia triggers proliferation in CA1 and neurogenesis in the DG in response to CA1 pyramidal neuronal death, independently of the reduced cerebral blood flow or the cell migration from subventricular zone (SVZ).     

Neurogenesis in the striatum of the quinolinic acid lesion model of Huntington's disease

The presence of ongoing neurogenesis in the adult mammalian brain raises the exciting possibility that endogenous progenitor cells may be able to generate new neurons to replace cells lost through brain injury or neurodegenerative disease. We have recently demonstrated increased cell proliferation and the generation of new neurons in the Huntington's disease human brain. In order to better understand the potential role of endogenous neuronal replacement in neurodegenerative disorders and extend our initial observations in the human Huntington's disease brain, we examined the effect of striatal cell loss on neurogenesis in the subventricular zone (SVZ) of the adult rodent forebrain using the quinolinic acid (QA) lesion rat model of Huntington's disease. Cell proliferation and neurogenesis were assessed with bromodeoxyuridine (BrdU) labeling and immunocytochemistry for cell type-specific markers. BrdU labeling demonstrated increased cell proliferation in the SVZ ipsilateral to the QA-lesioned striatum, resulting in expansion of the SVZ in the lesioned hemisphere. Quantification revealed that QA lesion-induced striatal cell loss produced a significant increase in the area of BrdU-immunoreactivity in the SVZ ipsilateral to the lesioned hemisphere between 1 and 14 days post-lesion compared with sham-lesioned animals, with the greatest increase observed at 7 days post-lesion. These changes were associated with an increase in cells in the anterior SVZ ipsilateral to the lesioned striatum expressing the antigenic marker for SVZ neuroblasts, doublecortin (Dcx). Importantly, we observed Dcx-positive cells extending from the SVZ into the QA-lesioned striatum where a subpopulation of newly generated cells expressed markers for immature and mature neurons. This study demonstrates that loss of GABAergic medium spiny projection neurons following QA striatal lesioning of the adult rat brain increases SVZ neurogenesis, leading to the putative migration of neuroblasts to damaged areas of the striatum and the formation of new neurons.     

Hippocampal adult neurogenesis is enhanced by chronic eszopiclone treatment in rats

The adult hippocampal dentate gyrus (DG) exhibits cell proliferation and neurogenesis throughout life. We examined the effects of daily administration of eszopiclone (Esz), a commonly used hypnotic drug and γ‐aminobutyric acid (GABA) agonist, compared with vehicle, on DG cell proliferation and neurogenesis, and on sleep–wake patterns. Esz was administered during the usual sleep period of rats, to mimic typical use in humans. Esz treatment for 7 days did not affect the rate of cell proliferation, as measured by 5‐bromo‐2′‐deoxyuridine (BrdU) immunostaining. However, twice‐daily Esz administration for 2 weeks increased survival of newborn cells by 46%. Most surviving cells exhibited a neuronal phenotype, identified as BrdU–neuronal nuclei (NeuN) double‐labeling. NeuN is a marker of neurons. Non‐rapid eye movement sleep was increased on day 1, but not on days 7 or 14 of Esz administration. Delta electroencephalogram activity was increased on days 1 and 7 of treatment, but not on day 14. There is evidence that enhancement of DG neurogenesis is a critical component of the effects of antidepressant treatments of major depressive disorder (MDD). Adult‐born DG cells are responsive to GABAergic stimulation, which promotes cell maturation. The present study suggests that Esz, presumably acting as a GABA agonist, has pro‐neurogenic effects in the adult DG. This result is consistent with evidence that Esz enhances the antidepressant treatment response of patients with MDD with insomnia.     

Growth behavior of cochlear nucleus neuronal cells on semiconductor substrates

Auditory brainstem implants provide sound information by direct stimulation of the cochlear nucleus to patients with dysfunctional or absent cranial nerve VIII. In contrast to patients with cochlear implants, the use of the auditory brainstem implants is less successful. This cannot be fully explained by the difference location of stimulation but a rather unspecific neuronal stimulation. The aim of this study was to further examine neuronal cells of the cochlear nucleus and to test their interactions with semiconductor substrates as a potential electrode material for improved auditory brainstem implants. The cochlear nuclei of postnatal day 7 rats were microsurgically dissected. The tissue was dissociated enzymatically and plated on coverslips as control and on the semiconductor substrates silicon or silicon nitride. After 4 days in culture the morphology and growth of dissociated cells was determined by fluorescence and scanning electron microscopy. Dissociated cells of the cochlear nucleus showed reduced cell growth on semiconductor substrates compared with controls. SEM analysis demonstrated close contact of neurons with supporting cells in culture and good adherence of neuronal growth cones on the used materials. These findings present basic knowledge for the development of neuron-electrode interfaces for future auditory brainstem implants.     

Young hippocampal neurons are critical for recent and remote spatial memory in adult mice

New granule cells are continuously generated throughout adulthood in the mammalian hippocampus. These newly generated neurons become functionally integrated into existing hippocampal neuronal networks, such as those that support retrieval of remote spatial memory. Here, we sought to examine whether the contribution of newly born neurons depends on the type of learning and memory task in mice. To do so, we reduced neurogenesis with a cytostatic agent and examined whether depletion of young hippocampal neurons affects learning and/or memory in two hippocampal-dependent tasks (spatial navigation in the Morris water maze and object location test) and two hippocampal-independent tasks (cued navigation in the Morris water maze and novel object recognition). Double immunohistofluorescent labeling of the birth dating marker 5-bromo-2'deoxyuridine (BrdU) together with NeuN, a neuron specific marker, was employed to quantify reduction of hippocampal neurogenesis. We found that depletion of young adult-generated neurons alters recent and remote memory in spatial tasks but spares non-spatial tasks. Our findings provide additional evidence that generation of new cells in the adult brain is crucial for hippocampal-dependent cognitive functions.     

Axo-somatic inhibition of projection neurons in the lateral nucleus of amygdala in human temporal lobe epilepsy: an ultrastructural study

Here, we report ultrastructural alterations in the synaptic circuitry of the human amygdala related to neuronal cell densities in surgical specimens of patients suffering from temporal lobe epilepsy (TLE). The neuronal cell densities quantified in the basolateral complex of amygdala were significantly reduced only in the lateral nucleus (LA) of TLE patients as compared to autopsy or non-Ammon’s horn sclerosis (AHS) controls (Nissl staining, immunostaining against the neuronal marker NeuN). For this reason, we focussed on the LA to perform a more detailed quantitative ultrastructural analysis, which revealed an inverse correlation between the number of axo-somatic inhibitory synaptic profiles at the somata of glutamic acid decarboxylase (GAD)-negative projection neurons and the extent of perisomatic fibrillary gliosis. In contrast, the density of GAD-immunoreactive interneurons positively correlated with the number of axo-somatic inhibitory synaptic profiles. The fibrillary material in perisomatic glial cell processes was preferentially labeled by the astroglial marker S100B. In addition, a qualitative study of the dendrites of GAD- and parvalbumin (PARV)-containing interneurons showed that they were often contacted by asymmetrical excitatory synapses. Our results are in line with anatomical data from rodents and cats, which show that amygdalar interneurons form axo-somatic inhibitory synapses on GAD-negative projection neurons, whereas the interneurons themselves receive excitatory input from recurrent collaterals of projection neurons and from cortico- and thalamo-amygdalar afferents. The structural reorganization patterns observed in the GABAergic circuitry are compatible with a reduced feedback or feed forward inhibition of amygdalar projection neurons in human TLE.     

Immunohistochemical Analysis of Nucleotide Excision Repair Factors XPA and XPB in Adult Rat Brain

To study the regional and cellular distribution of xeroderma pigmentosum group A and B (XPA and XPB) proteins, two nucleotide excision repair (NER) factors, in the mammalian brain we used immunohistochemistry and triple fluorescent immunostaining combined with confocal microscope scanning in brain slices of adult rat brain, including the cerebral cortex, striatum, substantia nigra compacta, ventral tegmental area, red nucleus, hippocampus, and cerebellum. Both XPA and XPB proteins were mainly expressed in neurons, because the XPA‐ or XPB‐immunopositive cells were only costained with NeuN, a specific neuronal marker, but not with glial fibrillary acidic acid, a specific astrocyte marker, in the striatum. Furthermore, XPA‐ and XPB‐positive staining were observed in the neuronal nuclei. Such subcellular distribution was consistent with the location of the NER in the cells. This study provides the first evidence that NER factors XPA and XPB exist in the nuclei of neurons in the brain, suggesting that the NER may play important roles in the process of DNA repair in adult brain neurons. Anat Rec, 291:775–780, 2008. © 2008 Wiley‐Liss, Inc.     

Capsaicin-induced neuronal death and proliferation of the primary sensory neurons located in the nodose ganglia of adult rats

To evaluate the potential for neuronal replacement following destruction of vagal afferent neurons, we examined nodose ganglia following i.p. capsaicin treatment of adult rats. Rats received capsaicin or vehicle followed by a regimen of 5'-bromo-2'-deoxyuridine injections (BrdU) to reveal DNA replication. Nodose ganglia were harvested at various times post-treatment and processed for 4',6-diamidino-2-phenylindole (DAPI) nuclear staining and immunofluorescence to estimate neuronal numbers and to determine vanilloid receptor, cleaved caspase 3, TUNEL, BrdU, the neuron-selective marker protein gene product (PGP) -9.5 and neurofilament-M-immunoreactivity. Twenty-four hours after capsaicin approximately 40% of nodose ganglion neurons expressed cleaved caspase 3-immunoreactivity and 16% revealed TUNEL staining, indicating that primary sensory neurons are killed by the capsaicin treatment of adult rats. The occurrence of neuronal death was confirmed by counts of DAPI-stained neuronal nuclei, which revealed >or=50% reduction of nodose neuron number by 30 days post-capsaicin. However, by 60 days post-capsaicin, the total numbers of neuronal nuclei in nodose ganglia from capsaicin-treated rats were not different from controls, suggesting that new neurons had been added to the nodose ganglia. Neuronal proliferation was confirmed by significant BrdU incorporation in nuclei of nodose ganglion cells immunoreactive for the neuron-specific antigen PGP-9.5 revealed 30 and 60 days post-capsaicin. Collectively, these observations suggest that in adult rats massive scale neurogenesis occurs in nodose ganglia following capsaicin-induced neuronal destruction. The adult nodose ganglion, therefore, provides a novel system for studying neural plasticity and adult neurogenesis after peripheral injury of primary sensory neurons.     

Dynamic changes of the neurogenic potential in the rat cochlear nucleus during post-natal development

Neuronal stem cells have been described in the post-natal cochlear nucleus recently. The aim of the study was to analyse the neurogenic potential in the cochlear nucleus from the early post-natal days until adulthood. Cochlear nuclei from Sprague–Dawley rats from post-natal day P3 up to P40 were examined. Neurosphere assays showed persistent neurosphere formation from the early post-natal days until adulthood. The numbers of generated neurospheres were fewer in older ages. Neurospheres were smaller, but displayed the same pattern of neuronal stem cell markers. The markers GFAP, MBP and ß-III Tubulin showed differentiation of dissociated cells from the neurospheres in all cells of the neuronal lineage. BrdU incorporation could be detected, in an age-dependent decrease, in whole-mount experiments of the cochlear nucleus on all examined days. BrdU co-labelled with Atoh1 and ß-III Tubulin. In addition, gene expression and cellular distribution studies of the neuronal stem cell markers displayed an age-dependent reduction in both quantity and numbers. The presented results display a possible neurogenic potential until adulthood in the cochlear nucleus by in vitro and in vivo experiments. The fact that this potential is highest at a critical period of development reveals possible functional importance for the development of the cochlear nucleus and the auditory function. The persistent neurogenic potential displayed until adulthood could be a neurogenic niche in the adult cochlear nucleus, which might be used for potential therapeutic strategies.     

Ischemic preconditioning enhances neurogenesis in the subventricular zone

Ischemic preconditioning (IPC) before subsequent prolonged ischemia is considered an emerging endogenous means of ischemic brain protection. We tested whether IPC induces endogenous neurogenesis in the subventricular zone (SVZ) and angiogenesis in the peri-ischemic area. Middle cerebral artery occlusion was administered to rats by filament insertion for 10 min (IPC) and/or 2 h (prolonged focal ischemia [PFI]). IPC alone increased 5'-bromo-2'-deoxyuridine (BrdU) (+) cells 2.5-fold in the SVZ compared with controls at 7 days. The numbers of BrdU/doublecortin (Dcx) or BrdU/neuronal nuclei (NeuN) double-labeled cells also increased, but extents of BrdU/glial fibrillary acidic protein (GFAP) double-labeling in the SVZ were not different. The IPC+PFI group showed about a 40% reduction in infarct volume. PFI increased BrdU (+) cells in the SVZ, and this was greatly enhanced by IPC treatment. The number of BrdU/Dcx double-labeled cells was strongly increased in ischemic brains administered IPC. Differentiation into mature neurons was also enhanced at 14 and 28 days. In addition, IPC significantly promoted angiogenesis in the ischemic penumbra as indicated by von Willebrand factor (vWF) staining. Our results indicate that IPC enhances neurogenesis in the SVZ even without subsequent PFI, and also enhances neurogenesis and angiogenesis after subsequent PFI. We conclude that IPC confers neuroprotection, and also promotes endogenous neurogenesis and angiogenesis.     

Chemical characterization of newly generated neurons in the striatum of adult primates

We recently demonstrated the existence of neurogenesis in the striatum of adult monkeys, but the number of striatal neurons generated under normal conditions was too small to establish their chemical phenotype. We therefore used brain-derived neurotrophic factor (BDNF), which promotes neuronal differentiation and survival and induces striatal neurogenesis in rodents, in an attempt to increase the number of newborn neurons in monkey striatum and facilitate their chemical characterization. An adenoviral vector (AdBDNF), encoding the human BDNF cDNA under the control of a strong promoter, was injected into the lateral ventricles (LVs) of adult squirrel monkeys, which were then treated with bromodeoxyuridine (BrdU). Two weeks after viral injection, numerous BrdU-positive cells were found within the striatum and many expressed microtubule-associated protein 2 (MAP-2) and neuronal nuclear protein (NeuN), two markers of mature neurons. Newborn neurons also expressed glutamic acid decarboxylase (GAD_65/67), calbindin (CB) and dopamine- and cAMP-regulated phosphoprotein of 32 kDa (DARPP-32), three markers of striatal projection neurons. We found no BrdU-positive neurons displaying the phenotype of striatal interneurons. Numerous BrdU-positive cells located near the subventricular zone (SVZ) coexpressed the migrating neuroblast markers polysialylated neural cell adhesion (PSA-NCAM) and doublecortin (DCX), suggesting that precursor cells could migrate from LVs to striatal parenchyma and develop a neuronal phenotype once they reach the striatum. However, many pairs of BrdU-positive nuclei were observed in the striatal parenchyma, suggesting that newborn neurons could also arise from resident progenitor cells. The present study demonstrates that a single injection of AdBDNF increases the number of newborn neurons into adult primate striatum and that newborn striatal neurons exhibit the chemical phenotype of medium-spiny projection neurons, which are specifically targeted in Huntington’s disease.     

Visualization of stress-responsive inhibitory circuits in the GAD65-eGFP transgenic mice

Here, we have revealed that a subset of GABAergic neurons in the mouse brain became activated during systemic stress response. Stress-induced expression of immediate early gene product c-Fos, as a marker of neuronal activation was visualized in a transgenic mouse line expressing enhanced green fluorescent protein (eGFP) under the control of the regulatory region of mouse glutamic acid decarboxylase (GAD) 65 gene. In most GABAergic regions egfp transgene expression corresponded to acknowledged distribution of GABA neurons. Ether inhalation, as a strong systemic stressor induced c-Fos expression throughout the stress-related circuit, and did not affect the distribution and expression of the eGFP-transgene. Stress provoked strong neuronal activation in the piriform cortex, midline thalamic nuclei, lateral septum (LS), bed nucleus of the stria terminalis (BNST), and in parvocellular part of the hypothalamic paraventricular nucleus (PVN) as revealed by c-Fos immunfluorescence. Cells in the LS, BNST, and AHA including the subparaventricular zone (SPVZ) displayed significant eGFP/c-Fos co-localization, revealing stress-responsive GABAergic neurons. None of the stress-activated neurons within the medial parvocellular subdivision of the PVN were GABAergic. Our present results suggest that stress-recruited GABAergic neuron populations are preferentially located in distinct limbic and hypothalamic regions and these neurons might be involved in an inhibitory mechanism that counteract the endocrine, autonomic and behavioral aspects of the stress response. Furthermore, the present GAD65-eGFP transgenic model seems to be a relevant tool to analyze inhibitory control of the central stress circuit at single cell level.     

Sustained increase in adult neurogenesis in the rat hippocampal dentate gyrus after transient brain ischemia

It is known that the number of newly generated neurons is increased in the young and adult rodent subventricular zone (SVZ) and dentate gyrus (DG) after transient brain ischemia. However, it remains unclear whether increase in neurogenesis in the adult DG induced by ischemic stroke is transient or sustained. We here reported that from 2 weeks to 6 months after transient middle cerebral artery occlusion (MCAO), there were more doublecortin positive (DCX+) cells in the ipsilateral compared to the sham-control and contralateral DG of the adult rat. After the S-phase marker 5-bromo-2'-deoxyuridine (BrdU) was injected 2 days after MCAO to label newly generated cells, a large number of BrdU-labeled neuroblasts differentiated into mature granular neurons. These BrdU-labeled neurons survived for at least 6 months. When BrdU was injected 6 weeks after injury, there were still more newly generated neuroblasts differentiated into mature neurons in the ipsilateral DG. Altogether, our data indicate that transient brain ischemia initiates a prolonged increase in neurogenesis and promotes the normal development of the newly generated neurons in the adult DG.     

Cytology, synaptology and immunocytochemistry of commissural neurons and their putative axonal terminals in the dorsal cochlear nucleus of the rat

The first binaural integration within the auditory system responsible for sound localization depends upon commissural neurons that connect the two symmetrical cochlear nuclei. These cells in the deep polymorphic layer of the rat dorsal cochlear nucleus were identified with the electron microscope after injection of the retrograde tracer, Wheat Germ Agglutinin conjugated to Horseradish Peroxydase, into the contralateral cochlear nucleus. Commissural neurons are multipolar or bipolar with an oval to fusiform shape. Few commissural neurons, most inhibitory but also excitatory, connect most of the divisions of the rat cochlear nuclei. The most common type is a glycinergic, sometimes GABAergic, moderately large cell. Its ergastoplasm is organized into peripheral stacks of cisternae, and few axo-somatic synaptic boutons are present. Another type of commissural neuron is a medium-sized, spindle-shaped cell, glycine and GABA-negative, with sparse ergastoplasm and synaptic coverage. A giant, rare type of commissural neuron is glycine-positive and GABA-negative, with short peripheral stacks of ergastoplasmic cisternae. It is covered with synaptic boutons, many of which contain round synaptic vesicles. Another rare type of commissural neuron is a moderately large cell, oval to fusiform in shape, immunonegative for both glycine and GABA, and contacted by many axo-somatic boutons. It contains large dense mitochondria and numerous dense core vesicles of peptidergic type. Some labelled boutons, mostly inhibitory and probably derived from commissural neurons, contact pyramidal, cartwheel, giant and tuberculo-ventral neurons. The prevalent inhibition of electrical activity in a cochlear nucleus observed after stimulation of the contralateral cochlear nucleus may be due to commissural inhibitory terminals which contact excitatory neurons such as pyramidal and giant cells. Other inhibitory commissural terminals which contact inhibitory neurons such as cartwheel and tuberculo-ventral neurons, may explain the stimulation of electrical activity in the DCN after contralateral stimulation.     

The localization and distribution of high affinity beta-nerve growth factor binding sites in the central nervous system of the adult rat. A light microscopic autoradiographic study using [125I]beta-nerve growth factor

Although beta-nerve growth factor is primarily known for its trophic role in the peripheral nervous system, recent reports have also revealed an inductive effect of beta-nerve growth factor on the cholinergic metabolism of the forebrain. To learn more about the significance and location of beta-nerve growth factor action in the central nervous system, the distribution of [125I]beta-nerve growth factor binding sites was studied by using the method of in situ receptor autoradiography and compared with the distribution of acetylcholinesterase, a sensitive enzyme marker of cholinergic neurons. The autoradiographic studies demonstrated strong, specific and saturable [125I]beta-nerve growth factor binding to several neuronal groupings in the forebrain and brainstem. beta-Nerve growth factor binding sites and strong acetylcholinesterase reactivity were jointly distributed in the forebrain on the medial septal nucleus, the diagonal band of Broca, the magnocellular basal nucleus and in the striatum. In the brainstem, beta-nerve growth factor binding sites were located on a number of neuronal groups in the reticular formation, the dorsolateral lemniscus and the cochlear nuclei. In contrast to the forebrain, less correlation was found with the distribution of acetylcholinesterase; no beta-nerve growth factor receptor expression was recorded on the cholinergic motor nuclei of the brainstem, while specific [125I]beta-nerve growth factor labeling could be located on the non-cholinergic cochlear nuclei. The present autoradiographic studies reveal a variety of tentatively beta-nerve growth factor receptor-positive neurons in the central nervous system. While strong correlation between the cholinergic metabolism and the presence of specific beta-nerve growth factor binding is demonstrated in the forebrain, this observation could not be extended to the brainstem, indicating the chemical diversity of central beta-nerve growth factor receptor-positive neurons.