Autophagy and cell death of Purkinje cells overexpressing Doppel in Ngsk Prnp-deficient mice

In Ngsk prion protein (PrP)-deficient mice (NP(0/0)), ectopic expression of PrP-like protein Doppel (Dpl) in central neurons induces significant Purkinje cell (PC) death resulting in late-onset ataxia. NP(0/0) PC death is partly prevented by either knocking-out the apoptotic factor BAX or overexpressing the anti-apoptotic factor BCL-2 suggesting that apoptosis is involved in Dpl-induced death. In this study, Western blotting and immunohistofluorescence show that both before and during significant PC loss, the scrapie-responsive gene 1 (Scrg1)--potentially associated with autophagy--and the autophagic markers LC3B and p62 increased in the NP(0/0) PCs whereas RT-PCR shows stable mRNA expression, suggesting that the degradation of autophagic products is impaired in NP(0/0) PCs. At the ultrastructural level, autophagic-like profiles accumulated in somatodendritic and axonal compartments of NP(0/0), but not wild-type PCs. The most robust autophagy was observed in NP(0/0) PC axon compartments in the deep cerebellar nuclei suggesting that it is initiated in these axons. Our previous and present data indicate that Dpl triggers autophagy and apoptosis in NP(0/0) PCs. As observed in amyloid neurodegenerative diseases, upregulation of autophagic markers as well as extensive accumulation of autophagosomes in NP(0/0) PCs are likely to reflect a progressive dysfunction of autophagy that could trigger apoptotic cascades.

Eye-blink conditioning is associated with changes in synaptic ultrastructure in the rabbit interpositus nuclei

Eye-blink conditioning involves the pairing of a conditioned stimulus (usually a tone) to an unconditioned stimulus (air puff), and it is well established that an intact cerebellum and interpositus nucleus, in particular, are required for this form of classical conditioning. Changes in synaptic number or structure have long been proposed as a mechanism that may underlie learning and memory, but localizing these changes has been difficult. Thus, the current experiment took advantage of the large amount of research conducted on the neural circuitry that supports eye-blink conditioning by examining synaptic changes in the rabbit interpositus nucleus. Synaptic quantifications included total number of synapses per neuron, numbers of excitatory versus inhibitory synapses, synaptic curvature, synaptic perforations, and the maximum length of the synapses. No overall changes in synaptic number, shape, or perforations were observed. There was, however, a significant increase in the length of excitatory synapses in the conditioned animals. This increase in synaptic length was particularly evident in the concave-shaped synapses. These results, together with previous findings, begin to describe a sequence of synaptic change in the interpositus nuclei following eye-blink conditioning that would appear to begin with structural change and end with an increase in synaptic number.

Ultrastructural study of cerebellar dentate nucleus astrocytes in chronic experimental model with valproate

The current study focuses on the morphogenesis of changes in the cerebellum dentate nucleus in the course of experimental valproate encephalopathy. Valproate - a broad spectrum antiepileptic and antipsychotic drug - chronically used in rats, intragastrically, once daily at a dose of 200 mg/kg b. w. for 1, 3, 6, 9 and 12 months, induced pronounced ultrastructural changes in the population of glial cells and nerve cells of the dentate nucleus of the cerebellum in the last two phases of the experiment. Astrocytic and neuronal lesions coexisted with a considerable damage to the elements of the blood-brain barrier of the cerebellar structure examined. The changes affected mainly the population of protoplasmic astrocytes lying loosely in a neuropile as well as astrocytes adhering to damaged large multipolar neurons. Focal proliferation of astrocytes was observed. Abnormal astrocytes showed marked swelling expressed by significantly decreased electron density of the cytoplasm that contained almost empty vacuolar structures and by a considerably reduced number of intracellular organelles. It was accompanied by dilation of endoplasmic reticular channels, loss of fibrillopoietic capacity of the cell and features of autophagocytosis. It should be assumed that the essential cause of protoplasmic astroglial damage of the cerebellar dentate nucleus could be associated, apart from the direct effect of valproate and/or its metabolites on these cells, with changes in structural elements of the blood-brain barrier of this CNS region.

Spinal Axonal Injury Induces Brief Downregulation of Ionotropic Glutamate Receptors and No Stripping of Synapses in Cord-Projection Central Neurons

Spinal cord injury often damages the axons of cord-projecting central neurons. To determine whether their excitatory inputs are altered following axonal injury, we used rat rubrospinal neurons as a model and examined their excitatory input following upper cervical axotomy. Anterograde tracing showed that the primary afferents from the cerebellum terminated in a pattern similar to that of control animals. Ultrastructurally, neurons in the injured nucleus were contacted by excitatory synapses of normal appearance, with no sign of glial stripping. Since cerebellar fibers are glutamatergic, we examined the expression of ionotropic receptor subunits GluR1-4 and NR1 for AMPA and NMDA receptors, respectively, in control and injured neurons using immunolabeling methods. In control neurons, GluR2 appeared to be low as compared to GluR1, GluR3, and GluR4, while NR1 labeling was intense. Following unilateral tractotomy, the levels of expression of each subunit in axotomized neurons appeared to be normal, with the exception that they were lower than those of control neurons of the nonlesioned side at 2-6 days postinjury. These findings suggest that axotomized neurons are only temporarily protected from excitotoxicity. This is in sharp contrast to the responses of central neurons that innervate peripheral targets, in which both synaptic stripping and reduction of their ionotropic glutamate receptor subunits persist following axotomy. The absence of an injury-induced trimming of afferents and stripping of synapses and the lack of a persistent downregulation of postsynaptic receptors might enable injured cord-projection neurons to continue to control their supraspinal targets during most of their postinjury survival. Although this may support neurons by providing trophic influences, it nevertheless may subject them to excitotoxicity and ultimately lead to their degenerative fate.

Optico-cochleo-dentate degeneration associated with severe peripheral neuropathy and caused by peroxisomal D-bifunctional protein deficiency

The clinical, neuroradiological, neuropathological and biochemical findings in a patient with optico-cochleo-dentate degeneration (OCDD; OMIM 258700) are presented in a severe case succumbing at the age of 4 years. The electron microscopic and biochemical data showed for the first time that OCDD may occur as the phenotypic expression of D-bifunctional protein deficiency, i.e., a peroxisomal disorder. The boy was born as the first child of healthy, consanguineous parents of Turkish origin. No other family members were affected. The main clinical symptoms consisted of muscle hypotonia ("floppy infant"), generalized epileptic fits, hypacusis, rotatory nystagmus, insufficient pupillary reactions, and mental retardation. Fibroblast cultures revealed D-bifunctional protein deficiency. Neuropathological examination displayed moderate frontoparietal and insular microgyria, and atrophy of the cerebellum. Loss of neurons was severe in the granular layer, the Purkinje cell band of the cerebellum, and rather complete in the dentate nucleus. A corresponding loss of myelinated fibers associated with characteristic periodic acid-Schiff-positive macrophages was most prominent in the white matter of the cerebellum. There was additional severe loss of myelinated fibers in the central portions of the optic nerve, reduction of the nerve fiber density in the cochlear nerve, and reduction of myelinated nerve fibers by about 80-90% in the sural nerve, which has not been studied in previous cases. At the electron microscopic level, characteristic inclusions mainly in perivascular macrophages and astrocytes were the most prominent finding. The inclusions usually showed a bilaminar structure, whereas trilaminar structures, typically seen in adrenoleukodystrophy, and multilaminar structures were less frequently seen.

Releasing the peri-neuronal net to patch-clamp neurons in adult CNS

The extracellular matrix of adult neural tissue contains chondroitin sulphated proteogylcans that form a dense peri-neuronal net surrounding the cell body and proximal dendrites of many neuronal classes. Development of the peri-neuronal net beyond approximately postnatal day 17 obscures visualization and often access by patch electrodes to neuronal membranes with the result that patch clamp recordings are most readily obtained from early postnatal animals. We describe a technique in which the surface tension of a sucrose-based medium promotes partial dissociation of thin tissue slices from adult tissue. Surface tension spreads the tissue and loosens the peri-neuronal net from neuronal membranes within minutes and in the absence of proteolytic enzymes. Furthermore, the extent of dissociation can be controlled so as to maintain the overall slice structure and allow identification of specific cell classes. Excellent structural preservation of neurons and dendrites can be obtained and full access by patch electrodes made possible for current- or voltage-clamp recordings in tissue well beyond the development of peri-neuronal nets. We demonstrate the feasibility of using this approach through patch recordings from neurons in the brainstem and cerebellum of adult gymnotiform fish and in deep cerebellar nuclei of rats as old as 6 months.

Projections of the basilar pontine nuclei and nucleus reticularis tegmenti pontis to the cerebellar nuclei of the rat

This study showed the precise projection pattern of the basilar pontine nuclei (BPN) and the nucleus reticularis tegmenti pontis (NRTP) to the cerebellar nuclei (CN), as well as the different anatomic features of BPN and NRTP projections. The staining of BPN or NRTP with biotinylated dextran labeled projection fibers to complementary topographic areas in the CN. In fact, BPN principally project to a rostrocaudally oriented column of the nucleus lateralis (NL), which at the midcentral level shifts to the lateroventral part of the nucleus, as well as to the caudolateral part of the nucleus interpositus posterioris. The NRTP projects to a rostrocaudal column of the NL, which at the midcentral level shifts medially, as well as to the nucleus interpositalis and to the caudal part of the nucleus medialis. BPN axons in the CN usually branch into short collaterals of simple morphology that involve small terminal areas, whereas NRTP axons branch into longer collaterals of complex morphology involving terminal areas of different sizes. Each site of injection is at the origin of a set of terminal areas in the CN. The set of projections from different BPN or NRTP areas were partially, but never completely, overlapping. Thus, the set of terminal areas in the CN was specific for each area of both BPN and NRTP. Injection of tetramethyl-rhodamine-dextran-amine into the CN stained cell bodies of BPN and NRTP with different repartition on the two sides. The study showed that CN are innervated by the contralateral BPN and not very much by the ipsilateral BPN, whereas they are innervated by NRTP bilaterally, even if with a contralateral prevalence. In conclusion, this study supports the hypothesis that both BPN and NRTP are concerned in the central program for skilled movements, even if they are probably involved in different functional roles.

Cerebello-thalamic synapses and motor adaptation

The cerebellum's influence on voluntary movement is mediated, in large part, through the cerebello-thalamo-cortical (CTC) pathway. Of particular relevance here are those neurons in the cerebellar nuclei that project, via thalamus, to pyramidal tract neurons in primary motor cortex. Several lines of evidence implicate cerebello-thalamic (CT) synaptic plasticity as a neural substrate underlying movement adaptation in adult animals. CT synapses exhibit a number of structural characteristics suggestive of a capacity for both formation of new synapses, and alterations in efficacy of transmission across existing synapses. Long-term potentiation can be evoked across CT synapses in vitro by high frequency stimulation, albeit in young animals. Evidence regarding the contribution of CT synaptic plasticity to two different types of movement adaptation in adult animals is conflicting. Adaptation involving a strengthening and re-coordination of voluntary movement is associated with an increase in density of CT synaptic boutons and an increase in number of synaptic vesicles available for immediate neurotransmitter release within each bouton. On the other hand, adaptation involving associative conditioning of a reduced sensorimotor neural circuit is associated with plasticity at thalamo-cortical but not CT synapses. These conflicting findings may reflect differences in the extent of synaptic re-organization that occurs at thalamic versus cortical levels, differences in the neural circuitry mediating each behavior, and/or differences in the spatio-temporal convergence of activity in the thalamus during the adaptive processes. It is concluded that CT synaptic plasticity can underlie movement adaptation if the adaptation requires reorganization of the cerebellum's influence on cerebral cortex.

Immunohistochemical study on the distribution of six members of the Kv1 channel subunits in the rat cerebellum

Voltage-gated K(+) (Kv) channels are critical for a wide variety of processes, and play an essential role in neurons. In the present study, we have demonstrated a unique pattern of expression of the six Kv1 channel subunits in the rat cerebellum, for the first time. The greatest concentration of Kv1.2 was found in the basket cell axon plexus and terminal regions around the Purkinje cells. Relatively weak immunoreactivity for Kv1.1 was also found in this area. The somatodendritic Purkinje cell areas were intensely stained with anti-Kv1.5 antibodies. In the cerebellar nuclei, the cell bodies of cerebellar output neurons showed strong Kv1.5 and Kv1.6 immunoreactivities in the nucleus medialis, interpositus and lateralis. Interestingly, Kv1.2 immunoreactivity was found in some neurons with their processes. Our immunohistochemical results may support the notion that the formation of heteromultimeric Kv channels possibly represents an important contribution to the generation of Kv channel diversity in the brain, especially in the cerebellum.

Corticonuclear projections of the cerebellum preserve both anteroposterior and mediolateral pairing patterns

The aim of the present study was to establish whether a diverging arrangement of the corticonuclear cerebellar projections exists and, if so, what relation it has with the inferior olivary complex. Iontophoretic injections of a 1 : 1 mixture of tetramethylrhodamine dextran amine and biotinylated dextran amine into the cerebellar cortex orthogradely labelled fibre terminals in the cerebellar nuclei and retrogradely labelled cell bodies in the inferior olivary complex. The injections were into A, B, C2, C3, D1 and D2 bands. These injections showed diverging projections to the cerebellar nuclei, with 'primary projections' directed to the nuclear region previously reported to be specifically connected with the injected band and 'secondary projections' directed to other nuclear regions. Secondary projections from the A, C2 and C3 bands diverged to nuclear regions primarily controlled by cortical bands lateral to those injected. Secondary projections from the D1, and D2 bands diverged to nuclear regions primarily controlled by cortical bands medial to those injected. Moreover, injections distributed along the D1 and D2 bands showed similar sets of nuclear targets, while those distributed along the A, C2 and C3 bands showed two sets of nuclear targets in relation to the anteroposterior location of the injected area within these bands. The cortical areas that projected to the same set of nuclear targets were innervated from single olivary regions, while those that projected to different sets of nuclear targets were innervated from different subsets of single regions of the inferior olive. The results suggest that the olivary bands of the cerebellar cortex project to the cerebellar nuclei with a diverging pattern that is organized in both the mediolateral and the anteroposterior axes.

Neurotoxicity studies on sucralose and its hydrolysis products with special reference to histopathologic and ultrastructural changes

Comparative neuropathological studies of 1,6-dichloro-1, 6-dideoxy-beta-D-fructofuranosyl-4-chloro-4-deoxy-alpha-D-galactopyra noside (sucralose), an equimolar mixture of 1,6-dichloro-1, 6-dideoxyfructose (1,6-DCF) and 4-chloro-4-deoxygalactose (4-CG), the hydrolysis products of sucralose, and 6-chloro-6-deoxyglucose (6-CG) were conducted in male and female mice and male marmoset monkeys, focusing on morphological changes in the central nervous system. 6-Chloro-6-deoxyglucose, previously reported to produce neurotoxic effects, served as the positive control and was administered by gavage at a daily dose of 500mg/kg. Sucralose and the sucralose hydrolysis products (sucralose-HP) were similarly administered to mice and marmosets at doses of up to 1000mg/kg for 21 and 28 days, respectively. No changes were detected in the central nervous system by light or electron microscopy in either of the species that received sucralose or its hydrolysis products. 6-Chloro-6-deoxyglucose, in contrast, induced symmetrical lesions in the deep nuclei of the cerebellum, brain stem and spinal cord with definitive neurological signs of CNS involvement.

Immunohistochemical studies of the structural bases of inhibition in the central cerebellar nuclei in mice

The distribution of glutamate decarboxylase-immunoreactive structures in the central nuclei of the cerebellum, its first afferent component, was studied at the light and electron microscope levels. Axosomatic, axodendritic, and axospinous synapses were detected, in which the presynaptic parts contained glutamate decarboxylase (GDC); this enzyme is involved in GABA synthesis. Additionally, these investigations revealed axoaxonal synapses in which both poles were GDC-reactive. The central nuclei of the cerebellum were found to have an intrinsic GABAergic system.

Pronounced loss of cell nuclei and anisotropic deformation of thick sections

The local deformation and variations in section thickness are studied in 100-microm thick vibratome sections of well-fixed human brain tissue. During processing, including drying on glass slides, the section thickness is reduced to less than half, but close to the edges there is less shrinkage of the section thickness. Close to both surfaces there is a pronounced reduction in the number of neuronal nucleoli. At the scale of the original section, the upper 15 microm and the lower 10 microm are depleted. The loss is most pronounced at the upper surface, which is unprotected during processing. In the central 70% of the section height, where one would ordinarily use an optical disector for sampling, there is no indication of non-uniform shrinkage. The simplest explanation for the observed loss of nucleoli is that all cells opened by the knife may lose their nuclei across an unprotected section surface. The observations do not generalize to other tissues and other preparation techniques, but illustrate the magnitude of some of the problems for uniform sampling and unbiased estimation in very thick sections. The uniform optical disector sampling of nucleoli in thick sections, as opposed to that of cell nuclei, raises a special problem, which is discussed briefly.

[Immunohistochemical study of structural basis of inhibition in central cerebellar nuclei]

Glutamatic acid decarboxylase (GAD): a synthetic enzyme for inhibitory neurotransmitter GABA, was studied in the central cerebellar nuclei. Synapses were found: morphological structures providing of inhibition in the central cerebellar nuclei.

Immunohistochemical localization of metabotropic glutamate receptors, mGluR7a and mGluR7b, in the central nervous system of the adult rat and mouse: a light and electron microscopic study

The distributions of two alternative splicing variants of metabotropic glutamate receptor mGluR7, mGluR7a and mGluR7b, were examined immunohistochemically in the rat and mouse by using variant-specific antibodies raised against C-terminal portions of rat mGluR7a and human mGluR7b. Many regions throughout the central nervous system (CNS) showed mGluR7-like immunoreactivities (LI). The distribution patterns of mGluR7-LI in the rat were substantially the same as those in the mouse, although some species differences were observed in a few regions. Intense mGluR7a-LI was seen in the main and accessory olfactory bulbs, anterior olfactory nucleus, islands of Calleja, superficial layers of the olfactory tubercle, piriform cortex and entorhinal cortex, periamygdaloid cortex, amygdalohippocampal area, hippocampus, layer I of the neocortical regions, globus pallidus, superficial layers of the superior colliculus, locus coeruleus, and superficial layers of the medullary and spinal dorsal horns. The distribution of mGluR7b was more restricted. It was intense in the islands of Calleja, substantia innominata, hippocampus, ventral pallidum, and globus pallidus. The medial habenular nucleus also showed intense mGluR7a-LI in the rat but not in the mouse. For both mGluR7a- and mGluR7b-LI, localization in the active zones of presynaptic axon terminals was confirmed electron microscopically at synapses of both the asymmetrical and symmetrical types. It is noteworthy that mGluR7a-LI is seen preferentially in relay nuclei of the sensory pathways and that both mGluR7a- and mGluR7b-LI are observed not only in presumed glutamatergic axon terminals, but also in non-glutamatergic axon terminals including presumed inhibitory ones. Thus, mGluR7 may play roles not only as an autoreceptor in glutamatergic axon terminals, but also as a presynaptic heteroreceptor in non-glutamatergic axon terminals in various CNS regions.

Differential number of glycine- and GABA-immunopositive neurons and terminals in the deep cerebellar nuclei of normal and Purkinje cell degeneration mutant mice

The total number of glycine-immunopositive (Gly+) neurons in the deep cerebellar nuclei (DCN) was quantified under normal conditions in wild-types (B6C3Fe) and compared with the Purkinje cell-deprived situation in Purkinje cell degeneration (PCD)-mutants by using an unbiased stereological method, the disector. In addition, the size and density of Gly+ terminals, the number of gamma-aminobutyric acid immunopositive (GABA+) somata and the somatal colocalization of Gly and GABA were determined. In both wild-types and PCD mutants, Gly+ somata are distributed relatively homogeneously among the different subdivisions of the DCN. However, in the complete volume of the DCN, which is reduced in PCD mutants by 52%, 8,582 Gly+ neuronal somata are present in wild-types and 14,637 in PCD mutants, which corresponds to an increase of 70.5% in the mutant. In contrast, the total number of GABA+ somata is almost the same in wild-types (16,713) and in PCD mutants (15,339). The number of neurons that colocalize both Gly and GABA is again almost identical in wild-types (3,976) and PCD mutants (3,861). Moreover, the size and number of Gly+ terminals contacting DCN neurons of PCD mutants are increased significantly compared to the wild-types. These data define for the first time the normal distribution of glycine and its somatal colocalization with GABA in the DCN of the mouse. In addition, it is shown that the Purkinje cell loss in PCD mutants leads to a significant increase in Gly+ somata and to a larger size and number of Gly+ boutons in the DCN. This suggests that the respective neurons are capable of exerting an enhanced inhibitory synaptic activity on their target neurons, substituting, at least in part, for the lost Purkinje cell (PC) inhibition. Probable correlations of these findings with the mildness of the motor disturbances found in PCD mutants are discussed.

Distribution pattern and ultrastructural localization of Rxt1, an orphan Na+/Cl(-)-dependent transporter, in the central nervous system of rats and mice

The cellular and subcellular localization of Rxt1 protein, an orphan Na+/Cl(-)-dependent transporter, was investigated in the central nervous system of rats and mice, with rabbit polyclonal antibodies specifically directed against its C-terminal region. At the light microscope level, the distribution of Rxt1, visualized by the immunoperoxidase method, was found to be similar in rats and mice. Labelled elements were present in numerous gray matter regions of the central nervous system, from the olfactory bulb to the spinal cord. In all labelled regions, immunoreactivity was confined to the neuropil where both a diffuse labelling of low intensity and an intense punctate staining were noted. To further identify the nature of the cellular elements bearing the punctate staining, possible changes in this labelling pattern were investigated: (i) in deep cerebellar nuclei and lateral vestibular nucleus of the Lurcher mutant mouse, in which all cerebellar Purkinje cells are missing and (ii) in the rat cervical spinal cord, 10 days after multiple resections of dorsal roots. The vast majority of the punctate structures, delineating the neuronal perikaryal and stem dendritic contours, had disappeared in the mutant mouse, providing evidence that they belong to Purkinje cell axon terminals. In rhizotomized rats, the intense labelling in laminae I and III had disappeared, demonstrating that it occurred in subclasses of axonal projections of primary afferent fibres. These results strongly suggest that Rxt1 is present in presynaptic axon terminals. The electron microscopic study was carried out in the hippocampus, cerebellum and lateral vestibular nucleus of control mice, where Rxt1-labelled punctate structures were found to be abundant. Immunostaining was confined to axon terminals, particularly in hippocampal and cerebellar mossy fibres and in Purkinje cell axonal terminations of the cerebellar deep nuclei and lateral vestibular nucleus. In the cerebellar cortex, axon terminals belonging to inhibitory local circuit neurons (basket and Golgi cells), were free of labelling. The observations reported in this study have shown that: (1) The Rxt1 transporter is neuron-specific, and is expressed by only some classes or even subclasses of neuronal systems. (2) This transporter can be encountered in excitatory axons using glutamate as neurotransmitter (hippocampal and cerebellar mossy fibres: primary afferent fibres), as well as in inhibitory axons known by their GABAergic nature (Purkinje cell axon terminals) where it might be involved in the re-uptake process of one or several molecules released from corresponding terminals.

Beta-adrenergic modulation of GABAergic inhibition in the deep cerebellar nuclei of F344 rats

The presence of norepinephrine (NE) and NE activated cells, in the deep cerebellar nuclei (DCN) of male F344 rats, was investigated using immunohistochemistry and electrophysiology, during iontophoresis of the beta-adrenergic agonist isoproterenol (ISO). During extracellular electrophysiology, GABA was iontophoretically applied to the cell and ISO was then co-applied in an attempt to modulate the GABAergic inhibition of cell firing in the DCN. Immunohistochemistry was used to detect tyrosine hydroxylase (TH) positive fibers in the DCN. Isoproterenol modulated GABAergic inhibition in 51% of the DCN cells recorded from. In addition, TH-positive fibers that appeared to make contact with DCN cells were found. Therefore, this study demonstrated that functional NE receptors exist in the DCN and NE appears to be present in fibers therein.

Morphology of axon collaterals of single climbing fibers in the deep cerebellar nuclei of the rat

Projection of inferior olive (IO) neurons to the deep cerebellar nuclei (CN) was investigated in the rat by reconstructing single axons that were labeled with biotinylated dextran amine injected into the IO. All reconstructed terminal arborizations in the CN (n = 18) arose as collaterals from climbing fibers (CFs). One to six nuclear collaterals were given off from each of six CFs that were reconstructed along the nearly entire pathway backward from cortical terminal arborizations to the IO. Nuclear collaterals were much thinner (0.2-0.3 micron in diameter) than stem axons projecting to Purkinje cells (0.7-1.4 microns). The number of swellings per a single nuclear collateral ranged from 24 to 118 (n = 18). Terminal arborizations of nuclear collateral originating from a single CF spread for some hundreds of micrometers and occupied a localized portion within the CN.

Astrocytic processes compensate for the apparent lack of GABA transporters in the axon terminals of cerebellar Purkinje cells

The aim of the present study was to evaluate the expression of two high affinity GABA transporters (GAT-1 and GAT-3) in the rat cerebellum using immunocytochemistry and affinity purified antibodies. GAT-1 immunoreactivity was prominent in punctate structures and axons in all layers of the cerebellar cortex, and was especially prominent around the somata of Purkinje cells. In contrast, the deep cerebellar nuclei showed few if any GAT-1 immunoreactive puncta. Weak GAT-3 immunoreactive processes were present in the cerebellar cortex, whereas GAT-3 immunostaining was prominent around the somata of neurons in the deep cerebellar nuclei. Electron microscopic preparations of the cerebellar cortex demonstrated that GAT-1 immunoreactive axon terminals formed symmetric synapses with somata, axon initial segments and dendrites of Purkinje cells and the dendrites of granule cells. Astrocytic processes in the cerebellar cortex were also immunolabeled for GAT-1. However, Purkinje cell axon terminals that formed symmetric synapses with neurons in the deep cerebellar nuclei lacked GAT-1 immunoreactivity. Instead, weak GAT-1 and strong GAT-3 immunoreactivities were expressed by astrocytic processes that enveloped the Purkinje cell axon terminals. In addition, GAT-3-immunoreactivity appeared in astrocytic processes in the cerebellar cortex. These observations demonstrate that GAT-1 is localized to axon terminals of three of the four neuronal types that were previously established as being GABAergic, i.e. basket, stellate and Golgi cells. GAT-1 and GAT-3 are expressed by astrocytes. The failure to identify a GABA transporter in Purkinje cells is consistent with previous data that indicated that Purkinje cells lacked terminal uptake mechanisms for GABA. The individual glial envelopment of Purkinje cell axon terminals in the deep cerebellar nuclei and the dense immunostaining of GAT-3, and to a lesser extent GAT-1, expressed by astrocytic processes provide a compensatory mechanism for the removal of GABA from the synaptic cleft of synapses formed by Purkinje cell axon terminals.

Altered axon terminals containing concentric lamellar bodies of cerebellar Purkinje cells in Mongolian gerbil

Altered axon terminals containing concentric lamellar bodies were observed in cerebellar and vestibular nuclei of the Mongolian gerbil. The terminals increased in number from 30 days of age onward, and reached about tenfold at 360 days. The numbers were the same in two gerbil strains with different susceptibility to spontaneous motor seizures by various stimuli, but about threefold those in Slc:Wistar rat.

Organisation of the cerebellar nucleus of the dogfish, Scyliorhinus canicula L.: a light microscopic, immunocytochemical, and ultrastructural study

Elasmobranchs possess a well-developed cerebellum with an associated cerebellar nucleus. To determine whether the organization of this nucleus is comparable with that of the deep cerebellar nuclei of mammals, we studied the dogfish cerebellar nucleus with light microscopic methods (Nissl stain, Golgi method, reduced silver stain, NADPH-diaphorase histochemistry and immunocytochemistry) and with electron microscopy. We found the dogfish cerebellar nucleus to consist of about 1,050 large neurons, the ratio of Purkinje cells to cerebellar nucleus neurons being about 17:1. Immunocytochemistry showed large glutamatergic neurons in the main portions of the nucleus and small glutamate- and/or alpha-aminobutyric acid (GABA)-immunoreactive cells in the subventricular region of the nucleus. Large glutamatergic neurons corresponded to bipolar or triangular cells revealed by Golgi methods. Application of horseradish peroxidase to the cerebellar cortex produced the labelling of beaded fibres of Purkinje cells in the cerebellar nucleus. Unlike in mammals, GABAergic innervation of the cerebellar nucleus was scare: Purkinje cell axon terminals in the cerebellar nucleus did not appear to be GABA-immunoreactive, most GABAergic fibres being found in the subventricular neuropile. Some fibres immunoreactive to serotonin and somatostatin were also observed in the subventricular neuropile of the cerebellar nucleus. Three neuron types were distinguished with electron microscopy (types A to C). Type A cells were abundant and smooth-surfaced, and appeared to correspond to Golgi-impregnated neurons and large glutamate-immunoreactive cells. Type B neurons were scarce and possessed dendrites covered by sessile or stalked spines. Type C neurons were small cells located mainly in the medialmost region of the nucleus and corresponded to subventricular glutamate- and GABA-immunoreactive cells. Six types of synaptic bouton were observed (types I to VI). The most abundant (type I boutons) made symmetrical contacts and appeared to correspond to Purkinje cell axons. Type I boutons were the only type observed on perikarya and initial axon segments of type A cells. Type IV and type V boutons made complex glomerular-like asymmetrical contacts with spines of type B cells. Type VI boutons appeared to correspond to peptidergic and/or monoaminergic axons. The functional significance of these results is discussed.

Ultrastructural localization of the plasmalemmal calcium pump in cerebellar neurons

In a previous study, fluorescence labeling of a plasmalemmal ATPase protein with the 5F10 monoclonal antibody revealed prominent antigen in the cerebellar molecular layer surrounding the somata and dendrites of Purkinje cells. In the present study, this antibody labeled with silver enhanced nano-sized gold particles on semithin plastic sections revealed a clearly demarcated plasma membrane outlining the somata and entire dendritic arbors of Purkinje cells including their spines. Ultrastructural analysis of horseradish peroxidase preparations showed reaction product along the plasmalemma and extending on to the sub-plasmalemmal endoplasmic reticulum. In the granular layer, somata of granule cells were reactive, as were their dendritic extensions into glomeruli where reactive claws surrounded voids formed by mossy fiber rosettes. Somata and dendrites of cerebellar nuclear cells also had reactive zones that were limited to the plasma membrane and a narrow zone of the sub-plasmalemmal endoplasmic reticulum. Comparative labeling of this protein and P channel protein revealed similar plasmalemmal locations. This study shows that a specific calcium ATPase pump protein is located on the plasmalemma of certain types of cerebellar neurons. The ultrastructural distribution of calcium pump and P channel antibodies occurred in punctate sites along the plasma membrane of dendrites and spines of Purkinje cells. The close association between P-type calcium channels and the plasma membrane calcium pump is consistent with rapid extrusion of intracellular calcium from neurons endowed with large numbers of voltage-gated calcium channels.

Ultrastructural localization of a voltage-gated K+ channel alpha subunit (KV 1.2) in the rat cerebellum

A highly specific monoclonal antibody and pre-embedding immunocytochemistry were employed to examine the distribution of the K+ channel, alpha subunit K(V)1.2 in the rat cerebellum. At the light microscopic level, the heaviest immunoreactivity was seen in the basket cell pinceau at the base of Purkinje cells, with lighter staining of basket and Golgi cell bodies and a punctate pattern in the granule cell and molecular layers. Electron microscopy was performed to identify the ultrastructural location of K(V)1.2 alpha subunit in these labelled structures. This revealed that the labelling of the pinceau was confined to the preterminal axonal plexus, the area immediately around the Purkinje axon initial segment being relatively devoid of staining. Basket cell parent axons were not immunostained, but gave rise to heavily stained fine processes. Immunoreactivity was also seen in myelinated axons in the granule cell layer and in the medial cerebellar nucleus, the staining being most concentrated at the juxtaparanodal regions of the axons. An unusual pattern of staining was seen in some mossy fibre terminals, with staining restricted to fine protuberances of mossy fibre glomeruli. Structures contacted by these protuberances included adjoining glial processes. Immunostaining was absent from Purkinje cell bodies, dendrites, their axon initial segments and their terminals in the medial cerebellar nucleus. In this study, the alpha subunit K(V)1.2 was localized to a number of different cell types in the cerebellum. Each neuronal type displays a distinct subcellular distribution of the subunit.

The use of electron microscopic immunocytochemistry with silver-enhanced 1.4-nm gold particles to localize GAD in the cerebellar nuclei

Silver enhancement of small gold particles can be used with pre-embedding immunocytochemistry to analyze the distribution of label over cell organelles. We have developed a method that improves tissue morphology, has good penetration of reagents, and allows greater control of silver enhancement of 1.4-nm gold. In this study we analyzed the distribution of glutamic acid decarboxylase (GAD), a synthetic enzyme for the inhibitory neurotransmitter gamma-aminobutyric acid (GABA), in the cerebellar nuclei of the mouse. Pre-embedding immunocytochemistry was carried out on brain sections fixed with high concentrations of glutaraldehyde and sodium metabisulfite. After incubations with a monoclonal antibody to GAD and a 1.4-nm NanoGold-labeled secondary antibody, sections were silver-enhanced with N-propyl gallate as a reducing agent and MES as a new buffer system. In the cerebellar nuclei, GAD label was specifically localized in axon terminals over clusters of synaptic vesicles. These terminals formed axosomatic and axodendritic contacts. The majority of GAD-labeled terminals had cytological characteristics indicating their origin from Purkinje cells, which are known to contain GAD.

Insulin-like growth factor-1 mRNA is increased in deafferented hippocampus: spatiotemporal correspondence of a trophic event with axon sprouting

Deafferentation is known to induce axonal sprouting in adult brain, but the signals that direct this response are not understood. To evaluate the possible roles of insulin-like growth factor-1 (IGF-1) and basic fibroblast growth factor (bFGF) in central axonal sprouting, the present study used in situ hybridization to evaluate IGF-1 and bFGF mRNA expression in entorhinal deafferented rat hippocampus. Alternate tissue sections were processed for Fink-Heimer impregnation of axonal degeneration, Bandeiraea simplicifolia (BS-1) labeling of microglia, and glial fibrillary acidic protein immunocytochemistry. In control hippocampus, IGF-1 mRNA was localized to a few neurons, with no labeled cells in the dentate gyrus molecular layer; bFGF cRNA hybridization was diffuse in dendritic fields but was dense in CA2 stratum pyramidale. Both mRNA species were increased by deafferentation. The distribution of elevated IGF-1 mRNA corresponded precisely to fields of axonal degeneration and was greatest in the dentate gyrus outer molecular layer and stratum lacunosum moleculare. In these fields, IGF-1 mRNA was elevated by 2 days, reached maximal levels at 4 days, and declined by 10 days postlesion. Double labeling revealed that the majority of IGF-1 cRNA-labeled cells were microglia. In deafferented hippocampus, bFGF mRNA was broadly increased across fields both containing and lacking axonal degeneration. In the dentate, bFGF mRNA levels peaked at 5 days postlesion and remained elevated through 14 days. These results demonstrate that reactive microglia within deafferented hippocampal laminae express IGF-1 mRNA just prior to and during the period of reactive axonal growth and suggest that IGF-1 plays a role in directing the sprouting of spared afferents into these fields.

Denervation induced abnormal phosphorylation in hippocampal neurons

This study demonstrates that combined dopaminergic and cholinergic denervation of the hippocampus results in the appearance of morphologically altered, Tau reactive, apical dendrites of granule cells in the rat dentate gyrus. The denervated granule cells and their apical dendrites also display immunoreactivity to a mitogen-activated protein kinase, ERK-1, and also evidence of abnormal phosphorylation of these dendrites as revealed by SMI-31 immunoreactivity. Dopaminergic denervation alone also causes mitogen activated protein kinase reactivity without the Tau-reactive apical dendrities. These results suggest an analogy to synaptophysin loss and the appearance of dendritic threads described in Alzheimer's disease (AD), as an early stage in the formation of neurofibrillary tangles (NFT). This is the first animal model in which abnormal phosphorylation of Tau has been shown to be produced experimentally in vivo.

Morphological changes in the hippocampus in amygdaloid kindled mouse

To clarify the origin and maintenance of epileptogenesis, morphological changes in the hippocampus of amygdaloid-kindled mice were analyzed at different stages of kindling. The granule cell size in dentate gyrus and the pyramidal cell size in CA1 were clearly decreased depending on seizure stage. The cell size in CA2 was increased and density in dentate gyrus and CA2 was reduced, significantly. The morphological changes in hippocampus associated with kindling must be closely related to the acquisition and the maintenance of epileptogenesis. The results support the hypothesis that seizure-induced damage of neurons may lead to formation of new synaptic connections that produce abnormal hyperexitability and result in seizures.

The substantia nigra pars reticulata, seizures and Fos expression

The induction of the proto-oncogene c-fos has been used extensively to identify spatially distributed neural systems activated by seizures. The substantia nigra pars reticulata (SNpr) has been implicated as a critical structure in neural networks involved in the modulation of seizure expression, yet the SNpr has not been reported to express Fos following seizures induced in a variety of seizure paradigms. In this study we determined whether (1) the temporal characteristics of Fos induction in the SNpr were different than those of other brain areas following kindled seizures, (2) neurons in the SNpr possess the cellular machinery to express Fos, (3) Fos can be induced in SNpr by direct electrical stimulation, and (4) Fos expression is induced in the SNpr following kainate or pilocarpine-induced status epilepticus. Results indicate that Fos is not induced in SNpr at any time point (1-12 h) after kindled seizures, and that serum response factor, a constitutively expressed nuclear protein necessary for Fos expression, is present in SNpr neurons. Results further indicate that Fos expression in the SNpr is induced following either direct electrical stimulation or pilocarpine status, but not status elicited by kainate. We conclude that, in so far as the SNpr represents a critical structure for modulating seizure expression, seizure activity does not represent a sufficient stimulus to induce Fos in SNpr neurons. Further, the neural networks defined by Fos expression following seizure may be incomplete, and should be interpreted conservatively.

New observation on ubiquitinated neurons in the cerebral cortex of multiple system atrophy (MSA)

To investigate neuronal damage in the cerebral cortex in patients with multiple system atrophy (MSA), immunohistochemical stainings were carried out on the prefrontal cortex, the hippocampus, the precentral gyrus, the supplementary motor cortex and the occipital cortex in 6 cases of MSA and 6 controls, using antibodies against ubiquitin, tau protein and neurofilaments (BF10, RT97, 147). In MSA cases, a variable number of neuronal ubiquitinated inclusions were observed in the granule cell layer of the dentate gyrus (3/6) and the prefrontal cortex (3/6). An increased number of ubiquitinated dots-like structures were also observed in the parahippocampal gyrus of MSA cases (4/6) in comparison with controls. These results showed further evidence of neuronal damage in the cerebral cortex in MSA and strongly suggest a relationship between the cerebral cortical pathology and occasional manifestation of cognitive deficits in some MSA cases.

Excitatory and inhibitory effects of A1 and A2A adenosine receptor activation on the electrically evoked [3H]acetylcholine release from different areas of the rat hippocampus

The modulation by adenosine analogues and endogenous adenosine of the electrically evoked release of [3H]acetylcholine ([3H]ACh) was compared in subslices of the three areas of the rat hippocampus (CA1, CA3, and dentate gyrus). The mixed A1/A2 agonist 2-chloroadenosine (CADO; 2-10 microM) inhibited, in a concentration-dependent manner, the release of [3H]ACh from the three hippocampal areas, being more potent in the CA1 and CA3 areas than in the dentate gyrus. The inhibitory effect of CADO (5 microM) on [3H]ACh release was prevented by the A1 antagonist 1,3-dipropyl-8-cyclopentylxanthine (DPCPX; 50 nM) in the three hippocampal areas and was converted in an excitatory effect in the CA3 and dentate gyrus areas. The A2A agonist CGS-21680 (30 nM) produced a greater increase of the evoked release of [3H]ACh in the CA3 than in the dentate gyrus areas, whereas no consistent effect was found in the CA1 area or in the whole hippocampal slice. The excitatory effect of CGS-21680 (30 nM) in the CA3 area was prevented by the adenosine receptor antagonist 3,7-dimethyl-1-propargylxanthine (10 microM). Both adenosine deaminase (2 U/ml) and DPCPX (250 nM) increased the evoked release of [3H]ACh in the CA1 and CA3 areas but not in the dentate gyrus. The amplitude of the effect of DPCPX and adenosine deaminase was similar in the CA1 area, but in the CA3 area DPCPX produced a greater effect than adenosine deaminase. It is concluded that the electrically evoked release of [3H]ACh in the three areas of the rat hippocampus can be differentially modulated by adenosine.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification of pontocerebellar axon collateral synaptic boutons in the rat cerebellar nuclei

Injections of the orthogradely transported tracer PHA-L into the basilar pontine nuclei or reticulotegmental nucleus of hooded rats produced labeling of pontocerebellar axons that distributed to the cerebellar cortex and nuclei. EM examination of the lateral and interposed cerebellar nuclei revealed that labeled pontocerebellar axon terminals formed synaptic boutons in the cerebellar nuclei that were morphologically different from the characteristic mossy fiber terminals observed in the cerebellar cortex.

A quantitative morphological analysis of the cerebellar nuclei in normal and lurcher mutant mice. II. Volumetric changes in cytological components

In the present study the stereological point counting method has been used to determine volumetric changes in the cytological components of the lurcher cerebellar nuclei. The volume fraction of neuronal somata was estimated, using semithin toludine blue stained sections. Seven categories of profiles were analyzed in electron micrographs: 1) dendrites, 2) boutons on dendrites, 3) boutons on somata, 4) myelinated fibers, 5) glial perikarya, 6) vascular elements, and 7) unclassified components. Volume fraction data indicate that the volumetric composition of the wild-type murine cerebellar nuclei is: 38% myelinated fibers, 8% neuronal somata, 11% dendrites, 10% boutons on dendrites, less than 1% boutons on somata, 2.5% glial somata, and 6% vascular elements. Unclassified elements, consisting primarily of glial processes and intercellular space, comprised 23% of the volume of the wild-type cerebellar nuclei. In lurcher, the loss of myelinated axons and boutons accounts for 59% of the atrophy of the cerebellar nuclei. Loss of nuclear neurons accounts for 2%, and a reduction in dendritic arbors for another 8.3% of this atrophy. The remaining 30.7% of the lost nuclear volume results from reduced volume of glial processes, vascular elements, and intercellular space.

The rostral dorsal cap and ventrolateral outgrowth of the rabbit inferior olive receive a GABAergic input from dorsal group Y and the ventral dentate nucleus

The dorsal cap and ventrolateral outgrowth of the inferior olive are involved in the control of eye movements. The caudal dorsal cap is predominantly involved in the horizontal optokinetic reflex; it receives most of its GABAergic input from the nucleus prepositus hypoglossi. In the present study, we determined the source of a major inhibitory input to the rostral dorsal cap and the ventrolateral outgrowth, which are the olivary subnuclei mainly involved in the "vertical" optokinetic reflexes. We studied these subnuclei in the rabbit with the use of retrograde tracing of horseradish peroxidase and anterograde tracing of wheat germ agglutinin-coupled horseradish peroxidase combined with postembedding immunocytochemistry. The ventral dentate nucleus of the cerebellum and dorsal group y project contralaterally to the rostral dorsal cap and ventrolateral outgrowth; this projection is entirely GABAergic. The terminals of this input form predominantly symmetric synapses with extraglomerular and intraglomerular dendrites; the remaining terminals are axosomatic. In addition, the dorsal cap and ventrolateral outgrowth contain significantly more crest synapses than any other olivary subnucleus. The terminals that form these crest synapses are derived from dorsal group y and/or the ventral dentate nucleus. None of the terminals in the dorsal cap or ventrolateral outgrowth was glycinergic.

The new monodendritic neuronal type within the adult human cerebellar granule cell layer shows calretinin-immunoreactivity

The distribution of calretinin immunoreactive structures within the granule cell layer of the adult human cerebellar cortex was studied using the avidin-biotin peroxidase method. Immunoreactivity is found in numerous fibers and glomerular formations, in Golgi- and Lugaro cells as well as in a recently described novel neuronal type, the monodendritic cell. The soma of the monodendritic neuron contains a faintly stained nucleus and issues a single short dendrite terminating in a tuft. Most probably, the tuft contributes to the formation of a glomerulum. Soma and tuft are of about the same size (diameter 10-18 microns). The number of monodendritic neurons is higher in the vermal than in the hemispheric part of the lobulus (lobulus VII) and is higher in lobulus X than in lobulus VII of the vermis.

Colocalization of neurotransmitters in the deep cerebellar nuclei

An abundance of glycine and glycine receptor immunoreactivities was found in all three parts of the deep cerebellar nuclei. Glycine immunoreactivity was restricted to small neurons throughout most of the deep cerebellar nuclei except for a few large positive neurons in the ventral part of the fastigial nuclei. In addition, glycine immunoreactivity was found in boutons outlining somata of large glycine negative neurons. Complementary to the glycine positive boutons was an intense glycine receptor immunoreactivity on large deep cerebellar nuclei neurons. Comparisons of immunoreactivities for glycine, GABA and aspartate in consecutive one micron sections revealed that many small neurons colocalized glycine and GABA, while some large neurons in the fastigal region colocalized glycine and aspartate. Ultrastructural investigations revealed glycine receptors on postsynaptic sites of dendrites and somata. Most boutons, which were presynaptic to glycine receptor sites, were filled with small flattened vesicles; however, a small percentage of boutons had round clear or dense core vesicles. Frequently, each bouton apposed multiple active zones on the dendrite or soma. One of these active zones was positive for glycine receptor and another was negative. This study supports: (1) glycine as a neurotransmitter in deep cerebellar nuclei, and (2) glycine and GABA colocalization in the same cell and bouton, but releasing to different receptor sites on the target neuron. Furthermore, the coexistence of glycine with GABA in the same deep cerebellar neuron may play an important role in controlling the conset and duration of signal transmission.

Projection from the deep cerebellar nuclei to the pedunculopontine nucleus in the squirrel monkey

Large injections of the anterograde tracer biocytin in the deep nuclei of the cerebellum of squirrel monkeys (Saimiri sciureus) led to a massive labeling of the superior cerebellar peduncle fibers which could be followed up to their major termination site in the thalamus. Along their course through the brainstem, biocytin-labeled fibers emitted fine collaterals that arborized profusely within the entire rostrocaudal extent of the pedunculopontine nucleus (PPN). These fibers were long, slightly varicose, and broke off into numerous shorter and thinner fibers whose terminal portions consisted of a few large varicosities that were often closely apposed to dendrites and cell bodies of PPN neurons. Some PPN cells that were contacted displayed immunoreactivity for choline acetyltransferase. Ultrastructural analysis revealed that synapses formed by cerebellar fibers in PPN were of the asymmetric type and occurred predominantly on dendrites of PPN neurons. Thus, beside the well established cerebellothalamic projection, our findings reveal the existence of a cerebellotegmental projection, whereby the cerebellum may influence the basal ganglia and/or the thalamus via a relay in PPN.

Reticular endings of Purkinje cell axons in the rat cerebellar nuclei: scanning electron microscopic observation of the pericellular plexus of Cajal

The pericellular plexus of Purkinje cell axons in the cerebellar nuclei was first recorded by Cajal (1911), using the Golgi method. The present study observed the axonal plexus in the rat by scanning electron microscopy after the plexus' detachment from the soma of target neurons by NaOH maceration. The pericellular plexus revealed numerous axons with ellipsoidal and moniliform swellings. They branched and crossed with each other to form, as a whole, a reticulum which enveloped the target neuron instead of multiple isolated boutons. Some axon terminals were separated from each other by thin glial processes, while others lacked such septa, thus being directly juxtaposed. Immunohistochemistry for spot 35 protein, a Purkinje cell-specific protein, detected similar beaded and reticular axons terminating on the neuronal somata, confirming their identification as Purkinje cells. Transmission electron microscopic observation showed that most of the axon terminals in question contained elliptical vesicles, characteristic for Purkinje cells. The vesicles were not accumulated toward small patchy areas of synaptic specialization but disseminated along the entire length of the terminal portion of axons.

Morphological response of endoplasmic reticulum in cerebellar Purkinje cells to calcium deprivation

Mobilisable intracellular Ca2+ stores are highly enriched in the cerebellum, particularly in Purkinje cells. We have detected, by light and electron microscopy, striking morphological changes in the presumed Ca2+ stores of Purkinje cells when slices of eight-day-old rat cerebellum were incubated in Ca(2+)-deficient media. After 30 min under these conditions, the endoplasmic reticulum became thinned and elongated. By 2 h, it was transformed into multilamellar, whorl-like inclusions with electron-dense cores. These changes were reversed on reintroduction of Ca2+. Analogous changes in other neurons were not observed. The results suggest that Ca2+ storage sites within Purkinje cells are capable of dramatic morphological change depending on the availability of Ca2+. The transformations may reflect, initially, depletion of Ca2+ from the stores and then homeostatic alterations in their capacity.

Intraparenchymal grafting of cerebellar cell suspensions to the deep cerebellar nuclei of pcd mutant mice, with particular emphasis on re-establishment of a Purkinje cell cortico-nuclear projection

In transplanting embryonic cerebellar grafts to the cerebellar cortex of "Purkinje cell degeneration" (pcd) mutant mice to replace missing Purkinje cells (PC), donor PC leave the graft and migrate to the molecular layer of the host. However, PC axons do not always reach the deep cerebellar nuclei of the host, which would be a key element in restoring much of the necessary inhibitory cortico-nuclear projection associated with normal cerebellar function. Rather, grafted PC axons often innervate a region containing deep cerebellar nuclei neurons inside the transplant, while the perikaryon migrates to the host molecular layer. In the present study, aimed at re-establishing a PC innervation of the deep nuclei, we implanted E12 cerebellar cell suspensions intraparenchymally to the deep cerebellar mass of the hosts. The development of grafted PC was monitored with 28-kDa calcium-binding protein (CaBP) immunocytochemistry at various times after transplantation. At short survival times (5 days after grafting), grafts were confined to the site of the original injection. At longer survival times (7-32 days after grafting), grafted PC formed a migratory stream that reached the cerebellar cortex of the host. The most robust graft development was seen 1 month after grafting, the longest survival time allowed in this series of experiments. At that time, clusters of donor PC were found both in the deep nuclei parenchyma and aligned along cortical folia. The orientation of the dendritic trees of PC that had migrated to the cortex was toward the pia. A CaBP-immunoreactive fibre plexus innervated the host deep cerebellar nuclei. The stream of grafted PC extended from the deep cerebellar nuclei to the cerebellar cortex of the host, indicating that donor PC could establish their axonal contacts in the deep nuclei and then move to their final cortical locality, thus recapitulating a migratory path normally taken during cerebellar ontogeny. It appears therefore that both from the pathophysiological and ontogenetic standpoints, the deep cerebellar nuclei represent the appropriate site for PC implantation in cerebellocortical atrophy.

Cytoarchitectural development of the human dentate nucleus: a Golgi study

Golgi-stained sections of the human cerebellar dentate nucleus (DN) at various gestational ages were examined to study the dendritic proliferation and maturation of the DN neurons. Bipolar cells were seen at 14-15 weeks. By 19-20 weeks, three cell types were identifiable: bipolar, hemispheric and pyriform. The cells of the dorsomedial region matured earlier than those of the ventrolateral region. In addition to the above cell types, multipolar and nuclear boundary cells were observable at 24-25 weeks. The five cell types persisted during subsequent development. At no stage of development was any neuronal organizational pattern apparent. A remarkable dendritic proliferation occurred at 27-28 weeks. Spines and filiform processes were seen at 34 weeks of intrauterine life.

The GABAergic cerebello-olivary projection in the rat

Immunocytochemical detection of glutamate decarboxylase (GAD), the predominant biosynthetic enzyme of gamma-aminobutyric acid (GABA), reveals the presence of a dense GABAergic innervation in all parts of the inferior olive. One brain center that provides a substantial projection to the inferior olive is the cerebellar nuclei, which contain many small GABAergic neurons. These neurons were tested as a source of GABAergic olivary afferents by combining retrograde tract tracing with GAD immunocytochemistry. As expected from previous studies, injections of wheat germ agglutinin-conjugated horseradish peroxidase (WGA-HRP) into the inferior olive retrogradely label many small neurons in the interposed and lateral cerebellar nuclei and the dorsal part of the lateral vestibular nucleus, and fewer neurons in the ventro-lateral region of the medial cerebellar nucleus. These projections are predominantly crossed and are topographically arranged. The vast majority, if not all, of these projection neurons are also GAD-positive. The relative contribution of this projection to the GABAergic innervation of the inferior olive was tested by lesion of the cerebellar nuclei, or the superior cerebellar peduncle. Within 10 days the lesion eliminates most GAD-immunoreactive boutons in the principal olive, the rostral lamella of the medial accessory olive, the ventrolateral outgrowth, and the lateral part of the dorsal accessory olive ventral fold. Thus, the effectiveness of this depletion demonstrates that the cerebellar nuclei provide most of the GABAergic innervation to regions of the inferior olive known to receive a cerebellar projection. Moreover, when the lateral vestibular nucleus is damaged, the dorsal fold of the dorsal accessory olive is depleted of GABAergic boutons. The synaptic relations that boutons of the GABAergic cerebello-olivary projection share with olivary neurons were investigated at the electron microscopic level by GAD-immunocytochemistry, anterograde degeneration of the cerebellar axons or anterograde transport of WGA-HRP. All of these methods confirm that GABAergic, cerebello-olivary axon terminals contain pleomorphic vesicles, and synapse on various portions of olivary neurons, and especially on dendritic spines within glomeruli, often in very close proximity to the gap junctions that characteristically couple the dendritic profiles. These results demonstrate four major points: that virtually all of the GABAergic, and presumably inhibitory, neurons of the cerebellar and dorsal lateral vestibular nuclei are projection neurons; that a large portion of the inferior olive receives GABAergic afferents from the cerebellar nuclei; that a portion of the dorsal accessory olive receives GABAergic afferents from the dorsal lateral vestibular nucleus; and that cerebello-olivary fibers often synapse near gap junctions, and therefore could influence electrical coupling of olivary neurons.

Immunocytochemical localization of thyroid hormone receptors in the adult rat brain

It is generally accepted that thyroid hormones act at the genomic level through an interaction with specific nuclear receptors. Using a monoclonal antibody raised against the rat liver nuclear L-T3 receptor (NTR), we report here the immunocytochemical localization of T3 receptors in the adult rat brain. The strongest NTR immunoreactivity was found in the olfactory bulb, the hippocampus, the dentate gyrus, the amygdala areas, and the neocortex (layers III-VI). An intermediate NTR immunoreactivity was found in the hypothalamus, whereas the thalamus, the caudate-putamen, and the pallidum were weakly NTR-immunoreactive. In the cerebellum, a strong NTR immunoreactivity was found in the nuclei of Purkinje cells, in the internal granular layer, and in some nuclei of cells located in the molecular layer. In the brainstem, a strong NTR immunoreactivity was found in the lateral mamillary nucleus and the interstitial nucleus. A weak to moderate NTR immunoreactivity was observed in the central gray matter, while the substantia nigra and the interpeduncular nucleus were weakly stained. Furthermore, we also found NTR immunoreactivity in the nuclei of ependymocytes, epithelial cells of the choroid plexus, and cells located in the white matter. At the electron microscope level, we confirm that the immunoreactivity was not only localized in the nuclei of neurons but also in the nuclei of astrocytes and medium oligodendrocytes. This study provides new information concerning the distribution of NTR in the rat brain: (1) NTR are present not only in neurons but also in glial and ependymal cells, and (2) there is a regional and cellular heterogeneity in the distribution of NTR in the central nervous system.

GABAA/benzodiazepine receptor-like immunoreactivity in rat and monkey cerebellum

The cellular and subcellular localization of GABAA/benzodiazepine receptor-like immunoreactivity in the rat and monkey cerebellum has been studied with a monoclonal antibody (E9) directed against the alpha-subunit of purified GABAA/benzodiazepine receptors. At both the light and electron microscopic level E9 immunoreactivity is located in all 3 layers of the cerebellar cortex and within the deep cerebellar nuclei. The reaction product accumulates within the cytoplasm of neurons and their dendrites but axons are not immunoreactive. Glial cells in the white matter and the cortical layers are also unlabeled, although in some instances Bergmann glia do contain reaction product. The overall distribution and cellular and subcellular localization of E9 immunoreactivity is identical for both monkey and rat cerebellum. On the basis of cell size, morphology, and location it is evident that E9 immunoreactivity occurs in examples of all 5 neuronal types in the cerebellar cortex: Purkinje cells, Golgi type II cells, granule cells, and stellate and basket cells. However, the distribution of the reaction product within the cells is more selective. For example, electron microscopy demonstrates that axonal processes and terminals are not E9 immunoreactive with the single exception of the mossy fiber terminals in the granular layer. Also, examples of unlabeled axon terminals resembling those derived from Golgi type II cells, basket cells, and stellate cells form synapses with immunoreactive dendrites and cell bodies in the cortical layers. Finally, in the deep cerebellar nuclei unreactive axon terminals make symmetric synapses with immunostained neurons and dendrites. These results show that E9 monoclonal antibodies label neurons and portions of their processes which are postsynaptic in GABA-mediated inhibitory circuits, and demonstrates that this antiserum can be used as a morphological marker for cells which make GABAA/benzodiazepine receptors.

Cerebellar injury due to phenytoin. Identification and evolution of Purkinje cell axonal swellings in deep cerebellar nuclei of mice

The present study describes the identification and the ultrastructural and numerical evolution of Purkinje cell axonal swellings induced by phenytoin. Thirty male C57Bl/6J mice received phenytoin orally in doses up to 100 mg/kg daily and were killed after 3, 6, 10, 14, and 48 days of treatment. Light and electron microscopic investigations as well as morphometric analysis of cut surface area and numerical density of axonal swellings were performed. The swellings appeared as early as 6 days after initiation of treatment and gradually increased in size and frequency. Use of an anti-lymphocyte monoclonal antibody (CD 3), specifically cross-reacting with Purkinje cells, identified the swellings as dystrophic Purkinje cell axons. On grounds of their ultrastructural appearance they were classified into three distinct types occurring at different time intervals after phenytoin exposure. At 6 days, most axonal swellings contained loosely aggregated membranous vesicles and tubules in a finely granulated matrix (type 1). At 14 days, larger axonal swellings appeared characterized by the presence of three-dimensional networks of branched and anastomosing membranous tubules (type 2). At 48 days, even larger axons contained bodies of highly condensed membranous material of sometimes paracrystalline appearance (type 3). It is suggested that phenytoin-induced axonal pathology of Purkinje cells is a dynamic process characterized by the progressive accumulation of proliferating membranous material arranged in an increasingly complex fashion.

Corticotropin-releasing factor in olivocerebellar climbing-fiber system of monkey (Saimiri sciureus and Macaca fascicularis): parasagittal and regional organization visualized by immunohistochemistry

An antiserum directed against the human form of corticotropin-releasing factor (CRF) was utilized for immunohistochemical visualization of the distribution of this peptide in the inferior olivary nucleus and cerebellum of 2 monkey species (Saimiri sciureus, Macaca fascicularis). Colchicine pretreatment was not used. In both species, immunoreactivity was evident in the vast majority of neurons in the inferior olivary nucleus, with perikarya in the medial accessory olive exhibiting especially intense staining. In cerebellum, no labeled perikarya were present, but immunoreactive axons exhibiting the morphological characteristics of climbing fibers and their collaterals were observed in cortical and nuclear structures. In the cortex, most labeled axons were confined to the molecular and Purkinje cell layers. In the sagittal plane, individual axonal arbors originated from thick, isolated axons at the base of the molecular layer and repeatedly ramified as they extended toward the cortical surface. In coronal sections, only thin, paired profiles were present. Labeled processes also formed efflorescences in the granular layer of cortex and were evident as highly arborized axons in cerebellar nuclei. In each of these instances, the labeled elements resembled climbing fibers or their collaterals as visualized by other methods. Other labeled processes in the granular layer exhibited the morphological characteristics of mossy fiber axons. Immunoreactive, climbing-fiber-like axons were present in the molecular layer throughout the major regions of cerebellar cortex. However, the most intensely labeled of these axons were strikingly clustered within particular regions and parasagittal domains. In the vermis and intermediate zone, intensely labeled axons were present only within parasagittal zones similar in location to those defined by climbing fiber innervation from the medial accessory olive. Intensely labeled axons were also densely but uniformly distributed within the uvula, the medial region of the dorsal paraflocculus, and the dorsal region of the pyramis, areas that receive their climbing fiber input primarily from the medial accessory olive. Labeled fibers were much less dense and were not clustered in the lateral hemispheres. The present observation of CRF-like immunoreactivity in the monkey olivocerebellar pathway is compatible with the previous observation of CRF mRNA within olivary neurons of rat, baboon, and human (Young et al., 1986) and with recent immunohistochemical findings in rat (Sakanaka et al., 1987; Palkovits et al., 1987), cat (Cummings et al., 1988; Kitahama et al., 1988), sheep (Cummings et al., 1988), and human (Powers et al., 1987).(ABSTRACT TRUNCATED AT 400 WORDS)

Electron microscopic localization of type I protein kinase C in rat Purkinje cells

A monoclonal antibody against protein kinase C (PKC) was used for immunocytochemical studies of the type I PKC encoded by gamma-cDNA sequence (gamma-subspecies) in rat Purkinje cells. Dense gamma-subspecies-like immunoreactivity was found on the cell membrane and in the cytoplasm except within cell organelles of the perikaryon, dendrites, axon, and axon terminals. The nucleus was also stained but less heavily, and the nucleoli remained unstained. Synaptic vesicles in the axon terminals were densely stained. The results suggest that gamma-subspecies might be functionally involved in modulation of nuclear function and of pre- and postsynaptic functions including transmitter release in the rat Purkinje cells.

Sagittal organization of the olivocerebellonuclear pathway in the rat. II. Connections with the nucleus interpositus

The organization of the sagittal Zone C of the cerebellar cortex of the rat was studied with respect to its efferent projections and to its inferior olive (IO) afferent connections. Wheat-germ agglutinin conjugated to horseradish peroxidase was used as a tracer. Zone C has been defined as the cortical region projecting to the nucleus interpositus anterior (NIA) and posterior (NIP). The results show that, in spite of some differences, Zone C of the rat is homologous to that of the cat. Three subzones, C1, C2 and C3, were clearly identified. Subzone C1 appears as a longitudinal band of the cerebellar cortex interrupted at the level of lobules VIb,c and part of lobule VII. It is therefore divided into two sagittal segments, one anterior to lobules I to VIa adjacent to Zone B; and one posterior to lobules VII to VIII adjacent to Zone A. Both segments receive climbing fibres from the lateral aspect of the rostral two-thirds and the medial aspect of the caudal one-third of the dorsal accessory olive (DAO). The Purkinje cell axons from subzone C1 project to both the NIA and the NIP where they occupy the medial one-third of the nucleus. Subzone C2 consists of a continuous sagittal band of the cerebellar cortex and lies between Subzones C1 and C3. It receives climbing fibres from the rostral aspect of the medial accessory olive (MAO) and projects to the central aspect of the NIA and to the lateral half of the NIP. Subzone C3, which is lateral to Subzone C2 and medial to Zone D, appears as a sagittal band of cortex interrupted at the level of lobule VI. It receives climbing fibres from the medial aspect of the DAO and projects to the lateral aspect of the NIA. The orientation of the olivocerebellonuclear circuit is fundamentally sagittal not only in the cerebellar cortex but also in the nuclei and, although less sharply, in the inferior olive.

Sagittal organization of the olivocerebellonuclear pathway in the rat. I. Connections with the nucleus fastigii and the nucleus vestibularis lateralis

The organization of the afferent and efferent connections of the sagittal Zones A and B of the cerebellar cortex of the rat have been studied using wheat-germ agglutinin conjugated to horseradish peroxidase as a tracer. A single injection of this tracer into the cerebellar cortex allowed us to study, simultaneously, the crossed olivocortical connections (revealed by the retrograde transport) and the direct corticonuclear connections (revealed by the anterograde transport). The results demonstrate that the olivocerebellonuclear pathway is organized in a longitudinal direction so that for a given small injection of the tracer in one lobule of the cortex, a long sagittal band of the retrograde-labelled cells is obtained in the inferior olive, and a long sagittal band of the labelled terminals is obtained in the cerebellar nuclei. Zone A and Zone B have been arbitrarily defined as the cortical regions projecting, respectively, to the nucleus fastigii (NF) and the nucleus vestibularis lateralis (NVL). Zone A of the rat runs parasagitally from lobules I to IX as described in the cat, but in the posterior lobe it extends much more laterally than in the other mammals to include the lobulus paramedianus and crus I regions. The projections of Zone A to the NF recognize a mediolateral as well as a dorsoventral organization. Zone A receives climbing fibres exclusively from the caudal half of the medial accessory olive (MAO) with a further topographical organization in 4 distinct connections. Zone B of the rat is a narrow strip of the cortex lying adjacent to Zone A and extending from lobule I to VI. It receives climbing fibres from the caudolateral half of the dorsal accessory olive (DAO) and projects to the ipsilateral NVL with no other detectable organization. The majority of the labelled terminals end in the dorsal aspect of the NVL, but a non-negligible quantity also end in the ventral aspect.

A new combination of WGA-HRP anterograde tracing and GABA immunocytochemistry applied to afferents of the cat inferior olive at the ultrastructural level

In order to identify cerebellar terminals in the cat inferior olive which contain gamma-aminobutyric acid (GABA), a technique was developed combining anterograde transport of wheatgerm agglutinine-conjugated horseradish peroxidase (WGA-HRP) with gold-immunocytochemistry. With this technique both the HRP reaction product and the immunogold labelling can be visualized in a single ultrathin section. Our results suggest that most, if not all of the WGA-HRP-labelled cerebellar terminals in the rostral medial accessory olive (MAO) and the rostral principal olive (PO) are GABAergic. In an additional experiment the GABAergic innervation of the rostral MAO was studied in combination with WGA-HRP anterograde tracing from the rostral mesencephalon. In this case the WGA-HRP-labelled terminals were never found to be GABA-positive.