Distribution and characterization of the TRH receptors in the CNS of ataxic mutant mouse

The distribution of TRH receptors in the membrane fraction of the CNS in ataxic mutant mice (C3Hf/Nem-rol and C57BL/6j-tg) was studied. TRH binding sites in cerebellum and frontal lobe of the ataxic form and the non-ataxic heterozygotes of Rolling Mouse Nagoya were decreased in comparison with the controls, whereas those in the spinal cord of Rolling Mouse Nagoya and cerebellum of Tottering Mouse were increased in the ataxic mice over the controls. Kinetic studies were performed on cerebrum and cerebellum of the different ataxic mutant mice. Such species differences in the distribution of the TRH receptors have to be considered in the action of TRH in individual ataxia cases.     

Distribution and characterization of the gaba receptors in the CNS of ataxic mutant mouse

In an attempt to elucidate molecular pathogenesis of ataxia without cytological abberations in the cerebellum, Rolling Mouse Nagoya (C3Hf/Nem-rol) was used to study distribution of GABA receptors in membrane fractions. Among muscimol binding sites of various regions in the ataxic CNS, those in pons and medulla were significantly decreased (P<0.001) compared with control and non-ataxic heterozygote CNS, followed by cerebellum at a lower degree of significance (P<0.01). The kinetic studies demonstrated that dissociation constants of high- and low-affinity binding sites of muscimol of each control and those of ataxic mutant mouse were similar, i.e.,K _H=41 nM andK _L=1.1 M, respectively.GAD in the various regions was assayed, and it showed higher activity in the thalamus and hypthalamus, and lower activity in the cerebellum, of the ataxic mutant mouse as compared to that of the control mouse.     

Concentrations of catecholamines and indoleamines in the central nervous system of Wriggle mouse Sagami

1. The concentrations of norepinephrine (NE), 3-methoxy-4-hydroxyphenylglycol (MHPG), 5-hydroxytryptamine (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA) in the central nervous system of Wriggle mouse Sagami (WMS), which is a new ataxic mutant mouse, were studied. 2. NE and MHPG levels were increased most remarkably in the cerebellum. 3. 5-HT and 5-HIAA levels were increased most remarkably in the brain stem and spinal cord. 4. The present results suggest enhancement of catecholamine and indoleamine metabolism in the cerebellum and bulbospinal cord, respectively, of the WMS, and these changes seem relevant to the specific motor dysfunction of the WMS.     

Heterogeneity of γ-Aminobutyric Acid/Benzodiazepine/β-Carboline Receptor Complex in Rat Spinal Cord

The properties of muscimol, beta-carboline (BC), and benzodiazepine (BZD) binding to crude synaptic membranes were studied in the spinal cord and cerebellum of rats. In cerebellar membranes, the density of high-affinity [3H]muscimol and [3H]6,7-dimethoxy-4-ethyl-beta-carboline ([3H]BCCM) binding sites is almost identical to that of [3H]flunitrazepam ([3H]FLU) or [3H]flumazenil (Ro 15-1788; ethyl-8-fluoro-5,6-dihydro-5-methyl-6-oxo-4H-imidazo[1,5-a] [1-4]benzodiazepine-3-carboxylate). In contrast to the cerebellum, the number of muscimol and BC binding sites in rat spinal cord is approximately 20-25% of the number of FLU or flumazenil binding sites. Moreover, in spinal cord membranes, BC recognition site ligands displace [3H]-flumazenil bound to those sites, with low affinity and a Hill slope significantly less than 1; the potency of the different BCs in displacing [3H]flumazenil is 20-50-fold lower in the spinal cord than in the cerebellum. [3H]Flumazenil is not displaced from spinal cord membranes by the peripheral BZD ligand Ro 5-4864 (4'-chlorodiazepam), whereas it is displaced with low affinity and a Hill slope of less than 1 (nH = 0.4) by CL 218,872 (3-methyl-6-(3-trifluoromethylphenyl)-1,2,4-triazolol[4,3-b] pyridazine). These data suggest that a large number of BZD binding sites in spinal cord (approximately 80%) are of the central-type, BZD2 subclass, whereas the BZD binding sites in cerebellum are predominantly of the central-type, BZD1 subclass.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of methylmercury on the spontaneous and potassium-evoked release of endogenous amino acids from mouse cerebellar slices

The effects of methylmercury on the spontaneous and potassium-evoked release of endogenous amino acids from mouse cerebellar slices have been examined. Methylmercury induced a concentration-dependent increase in the spontaneous release of glutamate, aspartate, gamma-aminobutyric acid, and taurine from mouse cerebellar slices. Glycine release was slightly increased, but not in a concentration-dependent manner. The spontaneous release of glutamine from mouse cerebellar slices was not altered by any concentration of methylmercury examined (10, 20, and 50 microM). The tissue content of glutamate, gamma-aminobutyric acid, glutamine, and taurine decreased after exposure to methylmercury. Exposure of cerebellar slices to 20 microM methylmercury resulted in a significant enhancement in glutamate release during stimulation with 35 mM K+. This increase could be accounted for by the methylmercury-induced increase in spontaneous glutamate release. The increase in spontaneous release of glutamate and gamma-aminobutyric acid was independent of the availability of extracellular calcium. These results suggest that methylmercury increases the release of neurotransmitter amino acids, particularly gamma-aminobutyric acid and glutamate, by acting at intracellular sites to increase release from a neurotransmitter pool. The increase in the potassium-stimulated release of glutamate may reflect an increased sensitivity of the cerebellar granule cell to the effects of methylmercury. It is suggested that alterations in amino acid neurotransmitter function in the cerebellum may contribute to some of the neurological symptoms of methylmercury intoxication.     

NMDA Receptors in Rat Cerebellum and Forebrain: Subtle Differences in Pharmacology and Modulation

Abstract: Binding of [³H]glutamate, [³H]glycine, and the glutamate antagonist [³H]CGS-19755 to NMDA-type glutamate receptors was examined in homogenates of rat forebrain and cerebellum. Most glutamate agonists had a higher affinity at the [³H]glutamate binding site of cerebellar NMDA receptors as compared with forebrain, whereas all the glutamate antagonists examined showed the reverse relationship. The [³H]glycine binding site of forebrain and cerebellar NMDA receptors showed a similar pharmacology in both brain regions. In the cerebellum, however, [³H]glycine bound to a second site with a 10-fold lower affinity and with a pharmacology that resembled that of the glycine/strychnine chloride channel. [³H]Glutamate binding was not affected by glycine agonists or antagonists, nor was [³H]glycine binding affected by glutamate agonists in either forebrain or cerebellum. Both CGS-19755 and 3-(2-carboxypiperazin-4-yl)propyl-1-phosphonic acid, glutamate antagonists, reduced [³H]glycine binding in cerebellum, whereas only CGS-19755 was effective in forebrain. Glycine agonists and antagonists modulated [³H]CGS-19755 binding in forebrain and cerebellum to different extents in the two brain regions. From these studies we conclude that the cerebellar NMDA receptor has a different pattern of modulation at glutamate and glycine sites and that glycine may play a more important role in the control of NMDA function in the cerebellum as compared with forebrain.     

Characterization, Distribution, and Protein Kinase C-Mediated Regulation of [35S]Glutathione Binding Sites in Mouse and Human Spinal Cord

Abstract: We have characterized a high-affinity [³⁵S]-glutathione ([³⁵S]GSH) binding site in mouse and human spinal cord. [³⁵S]GSH binding sites in mouse and human spinal cord were observed largely within the gray matter in both the dorsal and ventral horns of spinal cord at cervical, thoracic, and lumbosacral segments. High-affinity [³⁵S]GSH binding was saturable, showing a B _max of 72 fmol/mg of protein and a K _D of 3.0 n M for mouse spinal cord and a B _max of 52 fmol/mg of protein and a K _D of 1.6 n M for human spinal cord. [³⁵S]GSH binding was displaceable by GSH, l -cysteine, and S -hexyl-GSH, but not by glutamate, glycine, or NMDA. These [³⁵S]GSH binding sites exhibited kinetic and saturation characteristics similar to GSH binding sites in rat brain astrocytes. To determine whether [³⁵S]GSH binding sites could be regulated by protein kinase C, we exposed human spinal cord sections to phorbol 12,13-diacetate for 1 h before ligand binding. Phorbol ester treatment increased [³⁵S]GSH binding by ∼60%, an effect that could be blocked by exposure of spinal cord sections to 1-(5-isoquinolinylsulfonyl)-2-methylpiperazine, a general protein kinase inhibitor. [³⁵S]GSH binding sites in the spinal cord of both species exhibited many of the characteristics of a receptor including saturable binding, high affinity, ligand specificity, and modulation by kinase activity. These data suggest that GSH is a neurotransmitter in the CNS.     

Cerebellar regulation mechanisms learned from studies on GluRdelta2

The amino acid sequence suggests that glutamate receptor delta2 (GluRdelta2) belongs to an ionotropic GluR (iGluR) subunit family. However, neither the direct binding to glutamate nor the incorporation into any native iGluRs has been demonstrated. One prominent feature of GluRdelta2 is its predominant expression at parallel fiber-Purkinje cell synapses in the cerebellum. Knockdown or knockout of GluRdelta2 impairs synaptic plasticity, stabilization, elimination, motor control, and learning. Therefore, GluRdelta2 plays a crucial role in the cerebellar function. Several ataxic spontaneous mutant mice have defects in the GluRdelta gene. Numerous proteins interacting with GluRdelta2 have been identified. Recent in vivo studies on GluRdelta2 knockout mice shed light on the mechanism by which GluRdelta2 deficiency causes ataxia and unveiled some secondary influence of the GluRdelta2 deficiency on the function of the central nervous system. Studies on GluRdelta2 might provide unique clues regarding not only the molecular mechanism of synaptic regulations but also the functioning mechanism of the entire cerebellar system.     

FGF/FGFR2 Signaling Regulates the Generation and Correct Positioning of Bergmann Glia Cells in the Developing Mouse Cerebellum

The normal cellular organization and layering of the vertebrate cerebellum is established during embryonic and early postnatal development by the interplay of a complex array of genetic and signaling pathways. Disruption of these processes and of the proper layering of the cerebellum usually leads to ataxic behaviors. Here, we analyzed the relative contribution of Fibroblast growth factor receptor 2 (FGFR2)-mediated signaling to cerebellar development in conditional Fgfr2 single mutant mice. We show that during embryonic mouse development, Fgfr2 expression is higher in the anterior cerebellar primordium and excluded from the proliferative ventricular neuroepithelium. Consistent with this finding, conditional Fgfr2 single mutant mice display the most prominent defects in the anterior lobules of the adult cerebellum. In this context, FGFR2-mediated signaling is required for the proper generation of Bergmann glia cells and the correct positioning of these cells within the Purkinje cell layer, and for cell survival in the developing cerebellar primordium. Using cerebellar microexplant cultures treated with an FGFR agonist (FGF9) or antagonist (SU5402), we also show that FGF9/FGFR-mediated signaling inhibits the outward migration of radial glia and Bergmann glia precursors and cells, and might thus act as a positioning cue for these cells. Altogether, our findings reveal the specific functions of the FGFR2-mediated signaling pathway in the generation and positioning of Bergmann glia cells during cerebellar development in the mouse.     

Density of NMDA-Coupled and Uncoupled 1-[1-(2-[3H]Thienyl)cyclohexyl]piperidine Recognition Sites in the Brain and Spinal Cord: Differential Effects of NMDA Agonists and Antagonists

Abstract: Binding of 1-[1-(2-[³H]thienyl)cyclohexyl]piperidine ([³H]TCP) to mouse brain and spinal cord membranes was studied using compounds selective for the NMDA-coupled 1-(1-phenylcyclohexyl)piperidine (PCP) and/or σ recognition sites. In both tissues, [³H]TCP labeled two populations of binding sites. Density of the low-affinity sites was approximately the same in both tissues, but the population of the high-affinity [³H]TCP sites was three times bigger in the brain than in the spinal cord. Self- and cross-displacement studies showed that the high-affinity [³H]TCP binding sites could be identical with NMDA receptor-coupled PCP sites, whereas the low-affinity [³H]TCP sites may be associated with σ binding sites in both tissues. The NMDA-coupled PCP sites labeled in the presence of 6.25 n M [³H]TCP constituted a much higher percentage of the total binding in the brain (75%) than in the spinal cord (44%). Consistent with this, reintroduction of glycine and glutamate significantly increased, but DA antagonists significantly inhibited [³H]TCP binding in the brain but not in the spinal cord. Together, these data suggest that a large component of [³H]TCP-labeled binding sites in the spinal cord may be associated with σ but not the NMDA receptor-coupled PCP sites.     

Synaptic Chemistry Associated with Aberrant Neuronal Development in the Reeler Mouse

Abstract: Pre- and postsynaptic neurochemical markers for several afferent and intrinsic neuronal systems were measured in the mouse mutant, reeler. In the neocortex of the reeler, the relative positions of the polymorphic and pyramidal cells were inverted but this was not associated with alterations in the content/mg protein of synaptic markers for noradrenergic [tyrosine hydroxylase (TH), norepinephrine (NE), NE uptake], cholinergic [choline acetyltransferase (ChAT), quinuclidinyl benzilate (QNB) binding], γ-aminobutyric acid (GABA)ergic (glutamate decarboxylase, GABA uptake, GABA receptors, GABA) or glutamatergic (glutamate uptake, receptors, glutamate) neurons. The laminar distributions of the hippocampal neurons were disrupted and associated with mild hypoplasia; consistent with this alteration, the content/mg protein of some GABAergic (GABA uptake) and glutamatergic (glutamate receptors) markers were slightly increased. The reeler cerebellum was characterized not only by misalignment of neurons but also by a marked loss of granule cells. Commensurate with the degree of cerebellar hypoplasia, the total amount of glutamate content, [³H]l-glutamate uptake activity, [³H]muscimol, and [³H]QNB ligand binding were reduced in the reeler cerebellum. In contrast, presynaptic markers for the noradrenergic (TH, NE) climbing fibers and the cholinergic (ChAT) mossy fibers were significantly increased/mg protein but their total content/cerebellum was near normal. Our data support suggestions that cerebellar granule cells use glutamate as their neurotransmitter and contain GABA and cholinergic receptors. The findings also suggest that misplaced cortical and cerebellar neurons retain normal neurochemical characteristics and that the morphologic alterations do not markedly affect the quantitative development of aminergic afferent systems.     

Fundamental study on ataxic mice (wriggle mouse Sagami)

Wriggle mouse Sagami (WMS), a newly discovered BALB/C mouse strain, is characterized by its locomotor instability, abnormal gait pattern and neck wriggling. Although the growth of WMS mice is delayed, compared with normal BALB/C mice, the brain size corresponds to the relatively smaller body weight. In gross or histological examinations no local atrophy appears in the cerebrum, cerebellum, brain stem or spinal cord. The c-GMP level in the WMS cerebellum is decreased, but the c-AMP level is normal. The ataxic gait is not improved significantly by the administration of thyrotropin releasing hormone (TRH). These results indicate that the mechanism inducing ataxia and abnormal gait pattern in WMS may be different from those in other genetically-determined ataxic mice, e. g., Rolling mouse Nagaya (RMN), PCD, Staggerer and Reeler.     

Chicken Ovalbumin Upstream Promoter-Transcription Factor II (COUP-TFII) regulates growth and patterning of the postnatal mouse cerebellum

COUP-TFII (also known as Nr2f2), a member of the nuclear orphan receptor superfamily, is expressed in several regions of the central nervous system (CNS), including the ventral thalamus, hypothalamus, midbrain, pons, and spinal cord. To address the function of COUP-TFII in the CNS, we generated conditional COUP-TFII knockout mice using a tissue-specific NSE-Cre recombinase. Ablation of COUP-TFII in the brain resulted in malformation of the lobule VI in the cerebellum and a decrease in differentiation of cerebellar neurons and cerebellar growth. The decrease in cerebellar growth in NSE^Cre/+/CII^F/F mice is due to reduced proliferation and increased apoptosis in granule cell precursors (GCPs). Additional studies demonstrated that insulin like growth factor 1 (IGF-1) expression was reduced in the cerebellum of NSE^Cre/+/CII^F/F mice, thereby leading to decreased Akt1 and GSK-3β activities, and the reduced expression of mTOR. Using ChIP assays, we demonstrated that COUP-TFII was recruited to the promoter region of IGF-1 in a Sp1-dependent manner. In addition, dendritic branching of Purkinje cells was decreased in the mutant mice. Thus, our results indicate that COUP-TFII regulates growth and maturation of the mouse postnatal cerebellum through modulation of IGF-1 expression.     

Changes in movement and ataxic gait with development in genetically ataxic mice: a comparison with the level of cerebellar cyclic nucleotide

Spontaneous movement and ataxic gait in ataxic mice showing various pathological changes in the cerebellum were investigated according to developmental stage by the open-field method of comparison with normal mice. As the cerebellum contains relatively high levels of cyclic nucleotide, its concentrations was measured by radioimmunoassay to elucidate the correlation between spontaneous movement and ataxic gait and the neurological changes. The movements of Rolling Mouse Nagoya (RMN), Weaver and Reeler mice without Purkinje Cell Degeneration (PCD) were found to decrease at 4 and 12 weeks of age. The degree of ataxic gait worsen in RMN, was unchanged in Reeler and improved in Weaver and PCD mice. The cerebellar c-GMP concentration of ataxic mice was decreased, while no significant changes in c-AMP concentration were found in comparison with normal mice. With development, the level of cerebellar c-GMP in Weaver mice increased, but this was not apparent in RMN, Reeler or PCD mice. The results of this investigation indicated that there may be some relation between the degree of ataxic gait and the level of cerebellar c-GMP in Weaver mice.     

[3H]GABA binding in the cerebellum of the reeler murine mutant

In the cerebellum of the reeler mutant mouse, characterized morphologically by depletion of the granule cell population and abnormal synapse formation, increased GABA concentration and alterations in [³H]GABA binding have been observed. This study shows decreased affinity of the Na⁺-independent, high affinity GABA binding component of synaptosomal membranes and an increased affinity of the Na⁺-dependent, high affinity GABA binding component in reeler cerebellar homogenate and synaptic membranes. In contrast to the changes in affinity, the number of both Na⁺-dependent and Na⁺-independent binding sites was not significantly altered. The decreased affinity of the Na⁺-independent GABA binding and the increased affinity of the Na⁺-dependent binding, evidenced only in cerebellar tissue, were interpreted to indicate, respectively, hypo- and hypersensitivity of the postsynaptic and presynaptic elements of cerebellar GABAergic synapses, induced by the depressed excitatory granule cell input and/or the increased mossy fiber contact with the ectopic Purkinje cells.     

Glutamate receptor binding to cat central nervous system membranes

L-[3H]Glutamate exhibited specific binding to fresh membranes of cat CNS under physiological conditions of pH and temperature. This binding occurred in the absence of sodium ions. Kinetic analysis of the data for cerebellum suggested the presence of two distinct binding sites: a high-affinity process (Kd = 0.33 microM) with a capacity of 15 pmol/mg protein and a low-affinity process (Kd = 1.8 microM) which had a capacity of 65 pmol/mg protein. Several structural analogues of glutamic acid were able to appreciably inhibit the binding of [3H]glutamate. The distribution of glutamate binding between 12 regions of the CNS was measured. The amygdaloid complex exhibited the highest binding followed by hippocampus > hypothalamus identical to visual cortex identical to thalamus identical to caudate nucleus > olfactory bulb identical to tectum identical to cerebellum > dorsal pons identical to medulla > cervical spinal cord. These findings are consistent with the binding of [3H]glutamate being to its receptor.     

Electrophysiological Representation of Scratching CPG Activity in the Cerebellum

We analyzed the electrical activity of neuronal populations in the cerebellum and the lumbar spinal cord during fictive scratching in adult decerebrate cats before and after selective sections of the Spino-Reticulo Cerebellar Pathway (SRCP) and the Ventral-Spino Cerebellar Tract (VSCT). During fictive scratching, we found a conspicuous sinusoidal electrical activity, called Sinusoidal Cerebellar Potentials (SCPs), in the cerebellar vermis, which exhibited smaller amplitude in the paravermal and hemisphere cortices. There was also a significant spino-cerebellar coherence between these SCPs and the lumbar sinusoidal cord dorsum potentials (SCDPs). However, during spontaneous activity such spino-cerebellar coherence between spontaneous potentials recorded in the same regions decreased. We found that the section of the SRCP and the VSCT did not abolish the amplitude of the SCPs, suggesting that there are additional pathways conveying information from the spinal CPG to the cerebellum. This is the first evidence that the sinusoidal activity associated to the spinal CPG circuitry for scratching has a broad representation in the cerebellum beyond the sensory representation from hindlimbs previously described. Furthermore, the SCPs represent the global electrical activity of the spinal CPG for scratching in the cerebellar cortex.     

Elevated immunoreactive-somatostatin levels in the brain of ataxic mutant mice

Immunoreactive-somatostatin (IR-SRIF) levels were investigated in the brain of 4 types of ataxic mice (Rolling Mouse Nagoya, Weaver, PCD, Staggerer) with different cerebellar pathologies. IR-SRIF concentrations (ng/mg) were found to be significantly elevated in both cerebellum and cerebrum of all ataxic mutant mice, IR-SRIF (ng/organ) was found to be increased in the cerebellum and cerebrum in Rolling Mouse Nagoya and PCD compared with control mice. The gel-filtration profile (Sephadex G-50) in the cerebellar extracts of Rolling Mouse Nagoya proved to be identical to that of control mice. Three peaks of IR-SRIF were found to be uniformly elevated in Rolling Mouse Nagoya, with the highest peak coinciding with authentic somatostatin-14. The present results suggest that elevated levels of IR-SRIF in the brain may play a role in the mechanism underlying the manifestation of ataxia in ataxic mutant mice, especially in Rolling Mouse Nagoya and PCD.     

Chromogranin A in neurons of the rat cerebellum and spinal cord: quantification and sites of expression.

Chromogranin A (CGA) is an abundant protein of dense-cored secretory vesicles in endocrine and neuronal cells. The present study, for the first time, compares CGA of neurons of the central nervous system with the CGA of adrenal origin. By S1 nucleus protection assay, we found that the 3' part of the CGA mRNA between exons 5-8 of the cerebellum and the spinal cord of the rat is homologous to that of the adrenal. In situ hybridization histochemistry revealed that CGA mRNA in the cerebellar cortex is present in cell bodies of Purkinje cells and in neurons of the deep cerebellar nuclei. The perikarya of these cells also exhibit CGA-like immunoreactivity. CGA mRNA and CGA-like immunoreactivity are also present in the motoneurons of the ventral, lateral, and dorsal horns of the rat spinal cord. The amounts of CGA, as determined by radioimmunoassay in cerebellum and spinal cord, were about one tenth of the amounts detected in the adrenal, adenohypophysis, or the olfactory bulb. The sites of CGA expression suggest that CGA may be involved in signal transduction in the motor system.     

ATP-Dependent Glutamate Uptake into Synaptic Vesicles from Cerebellar Mutant Mice

The ATP-dependent glutamate uptake system in synaptic vesicles prepared from mouse cerebellum was characterized, and the levels of glutamate uptake were investigated in the cerebellar mutant mice, staggerer and weaver, whose main defect is the loss of cerebellar granule cells, and the nervous mutant, whose main defect is the loss of Purkinje cells. The ATP-dependent glutamate uptake is stimulated by low concentrations of chloride, is insensitive to aspartate, and is inhibited by agents known to dissipate the electrochemical proton gradient. These properties are similar to those of the glutamate uptake system observed in the highly purified synaptic vesicles prepared from bovine cortex. The ATP-dependent glutamate uptake system is reduced by 68% in the staggerer and 57-67% in the weaver mutant; these reductions parallel the substantial loss of granule cells in those mutants. In contrast, the cerebellar levels of glutamate uptake are not altered significantly in the nervous mutant, which has lost Purkinje cells, but not granule cells. In view of evidence that granule cells are glutamatergic neurons and Purkinje cells are GABAergic neurons, these observations support the notion that the ATP-dependent glutamate uptake system is present in synaptic vesicles of glutamatergic neurons.