Autoradiographic localization of insulin-like growth factor II receptors in cerebellar cortex of weaver and Purkinje cell degeneration mutant mice

Autoradiography was used to visualize insulin-like growth factor II (IGF-II) receptors in the cerebellar cortex of weaver and Purkinje cell degeneration (pcd) mice. These mutants were selected for their respective absence of granule or Purkinje cells. Histological preparations confirmed a severe loss of granule cells in the cerebella of weaver mutants and an absence of Purkinje cells in those of pcd mutants. Autoradiographs showed specific IGF-II binding to the granule cell layer of the cerebellar cortex in control mice, and in pcd mutants. No specific [125I]human IGF-II binding was observed in the cerebellar cortex of weaver mutants. These studies suggest that specific IGF-II receptor sites are located on the granule cells of the cerebellum.     

Regional distribution and cell type-specific expression of the mouse F3 axonal glycoprotein: a developmental study.

The expression of the mouse axonal adhesive glycoprotein F3 and of its mRNA was studied on sections of mouse cerebellar cortex, cerebral cortex, hippocampus, and olfactory bulb from postnatal days 0 (P0) to 30 (P30). In cerebellar cortex, a differential expression of F3 in granule versus Purkinje neurons was observed. F3 was highly expressed during migration of and initial axonal growth from cerebellar granule cells. The molecule was then downregulated on cell bodies and remained expressed, although at low levels, on their axonal extensions. On Purkinje cells, F3 was strongly expressed on cell bodies and processes at the beginning of the second postnatal week; by P16 it was restricted to neurites of Purkinje cells subpopulations. In the cerebral cortex, the molecule was highly expressed on migrating neurons at P0; by P16, it was found essentially within the neuropil with a diffuse pattern. In the hippocampal formation, where F3 was expressed on both pyramidal and granule neurons, a clear shift from the cell bodies to neurite extensions was observed on P3. In the olfactory pathway, F3 was expressed mainly on olfactory nerve fibers, mitral cells, and the synaptic glomeruli from P0 to P3, with a sharp decline from P11 to P16. As a whole, the data show that F3 protein expression is regulated at the regional, cellular, and subcellular levels and suggest that, in different regions, it can be proposed as a reliable neuronal differentiation marker.     

Stability of GABAA/benzodiazepine receptor alpha 1 subunit mRNA expression in reeler mouse cerebellar Purkinje cells during postnatal development.

A [35S]cRNA probe was used for the visualization of GABAA/benzodiazepine (GABAA/BZ) receptor alpha 1 subunit mRNA in developing reeler mutant mouse cerebellum. A clear hybridization signal was observed throughout the malformed reeler cerebellum from birth. Labeling was associated with Purkinje cell bodies located in three subcortical masses. Additional labeled Purkinje cells were observed within the granule cell layer and at their normal position at the interface between the molecular and granule cell layers. All reeler Purkinje cells had comparable levels of grain density, regardless of their location within the cerebellar cortex. These results indicate that Purkinje cell malpositioning, and the resulting absence of a major complement of afferents throughout development, does not impair the expression of mRNA coding for the alpha 1 subunit of the GABAA/BZ receptor.     

Cerebellar histamine-H1 receptor distribution: An autoradiographic study of purkinje cell degeneration, staggerer, weaver and reeler mutant mouse strains

The distribution of 3H-mepyramine binding sites in cerebellae of normal mice and Purkinje cell degeneration, staggerer, weaver and reeler mutant mice was studied by light microscopic autoradiography. The binding of 3H-mepyramine to 20 micron coronal sections through the cerebellum and medulla had the characteristics expected of histamine-H1 receptor labeling. In the cerebellar cortex of normal mice, a high density of 3H-mepyramine binding was observed over the molecular layer and an intermediate density over the Purkinje cell layer, while the granule cell layer and white matter were almost devoid of labeling. The deep cerebellar nuclei were labeled to an intermediate density. In the 54 day old Purkinje cell degeneration mutant cerebellum, which is depleted of Purkinje cells, a greatly reduced labeling of the cerebellar cortex was observed. Labeling in the deep cerebellar nuclei was unaffected. In the 27 day old staggerer cerebellum, a mutation characterized by Purkinje cells which are almost devoid of spines and which do not form synaptic contacts with granule cells, a higher than normal grain density was seen over the cerebellar cortex, while normal grain density was observed over the deep cerebellar nuclei. The cerebellar cortex of 81 day old weaver mice, which is almost devoid of granule cells, had a high grain density over medial regions of the cortex, while the portion of the granule cell layer which remained relatively unaffected in the lateral parts of the cerebellum was unlabeled. The deep cerebellar nuclei had grain densities similar to littermate controls. In the 29 day old reeler cerebellae, which contain malpositioned Purkinje cells, high grain density regions corresponding to the heterotopically located Purkinje cells were observed. The present observations suggest that cerebellar cortical histamine-H1 receptors are associated predominantly with Purkinje cells. Furthermore, the expression of these H1 receptors appears not to be adversely affected by several alterations in the Purkinje cell environment, which have previously been shown to dramatically influence Purkinje cell morphology.     

Neuronal maturation in the normal and hypothyroid rat cerebellar cortex studied with monoclonal antibody MIT-23

By immunocytochemistry we have studied the expression of the mitochondria-associated polypeptide MIT-23 during the postnatal development of the normal and hypothyroid rat cerebellar cortex, in afferent fibers, and also in neurons of the cerebellar nuclei. The glial cells are never immunoreactive. In all neurons of the cerebellar cortex, MIT-23 expression always occurs after the final mitosis and migration are complete, and persists throughout adult life. Almost all MIT-23 expression begins postnatally. A few Purkinje cells are already immunoreactive at birth and the rest begin expression during the following two days. Immunoreactive Golgi and granule cells are found from postnatal day 4 (P4), basket cells from P10, and stellate cells from P16. Purkinje cells from different anteroposterior regions of the vermis express different levels of MIT-23 with higher staining intensities in lobules I to IV. These differences appear early in development and are retained in the adult. MIT-23 expression in the hypothyroid cerebellar cortex differs from that in control animals only in minor ways. However, sections immunoperoxidase-stained with anti-MIT-23 antibody reveal that, in addition to previously reported alterations in cerebellar development due to a shortage of thyroid hormones, Purkinje cell axonal development is slowed down in the hypothyroid condition, and occasional Purkinje cells in normal and especially in hypothyroid animals have their somata and or dendrites in ectopic locations. Analysis of these cells reveals a preferential direction of dendritic trunk growth in the direction of the molecular layer. Furthermore, secondary branching of ectopic dendrites is confined exclusively to the developing molecular layer, as in normal Purkinje cells, thus suggesting that neither the mature nor immature granule cell environment is sufficient to sustain normal dendritic development.     

Gene expression of Ca2+/calmodulin-dependent protein kinase of the cerebellar granule cell type or type IV in the mature and developing rat brain.

The localization and ontogenic changes of expression of the mRNA for Ca2+/calmodulin-dependent protein kinase of the cerebellar granule cell type or type IV (CaM kinase Gr or IV) in the rat brain were examined by in situ hybridization histochemistry. At the young adult stage, intense expression signals for this kinase mRNA were detected in the cerebellar granule cells, the hippocampal pyramidal cells, the dentate granule cells, and the piriform cortex. Moderate levels of the mRNA were expressed in the thalamic nuclei and the cerebral cortex. No distinct expression signals were detected in the Purkinje cells and most brainstem nuclei except for the pontine nuclei, locus ceruleus and inferior olive which showed weak expression. During development, two chronological patterns of changes in the gene expression for this kinase were discerned. The first was a high and persistent expression from the developing stages till the adult stage, which was observed in the cerebellar granule cells, the hippocampal pyramidal cells and the dentate granule cells. The other was a transiently high expression during limited developmental periods, which was observed in the Purkinje cells, neurons in the inferior olive, various brain stem nuclei, and the subventricular neuronal cells. These findings suggest that this Ca2+/calmodulin-dependent protein kinase is involved differentially in multiple Ca2+ signaling pathways in different developing and mature neurons.     

Concentrations of glutamic acid in cerebellar cortex and deep nuclei of normal mice and weaver, staggerer and nervous mutants

The concentrations of several free amino acids including glutamate were measured in cerebellar cortex and deep nuclei, and in cerebral cortex, from three neurological mutant mice, two of which lose most granule cell neurons in the cerebellar cortex (Weaver and Staggerer), and one of which loses cerebellar Purkinje cells (nervous).

(1) In Weaver and Staggerer, glutamate concentration was reduced to less than two-thirds of control values in both cerebellar cortex, where granule cells with all their axonal and dendritic processes reside, and in cerebellar deep nuclei where no granule cells are found.

(2) No other amino acids, including aspartate, were significantly reduced in cerebellar cortex and deep nuclei of either granuloprival mutant at 3 weeks of age.

(3) Glutamate concentration was normal in the cerebral cortex of Weaver and Staggerer mice.

(4) Glutamate concentration was normal in cerebella of heterozygous Weaver animals, in which 10–20% of the granule cells are missing.

(5) Glutamate was not reduced in either cerebellar cortex or deep nuclei of the Purkinje cell deficient mutant, nervous; only GABA, the Purkinje cell transmitter, was reduced significantly and only in the deep nuclei.

(6) An incidental finding was that the Staggerer mutation, previously recognized

to modify CNS structure only in the cerebellar cortex, causes a reduction of deep nuclear weight and protein to 30% of normal. No reductions were found in weight or protein in the deep nuclei of Weaver mutant mice.

We conclude that glutamate reduction in an area of cerebellum distant from granule cells and their processes cannot be explained by the absence of granule cells alone, and may indicate that a glutamate-utilizing component of cerebellar cortex and deep nuclei has become modified secondary to the granule cell deficit.     

Developmental expression of the cell cycle and apoptosis controlling gene,Lot1, in the rat cerebellum and in cultures of cerebellar granule cells

The Lot1 gene encodes a zinc finger protein that, in vitro, concurrently regulates apoptosis and cell cycle arrest and belongs to a recently identified family of proteins with oncogenic and tumor-supressor functions. The present study, based on the development of the first antibody reportedly produced against rat Lot1, examines protein expression during normal development of the rat cerebellum and following methylazoxymethanol (MAM) administration, which results in hypoplasia of the cerebellar granule cell population. Using light microscopic immunocytochemistry, specific immunostaining for the Lot1 protein was observed at postnatal days 2 to 7 in the superficial external granule layer composed primarily of proliferating neuronal precursor cells. Purkinje cells showed distinct nuclear labeling at P7. In the adult cerebellum, the overall low Lot1 level was essentially associated with Purkinje cells. Experimentally altered developmental conditions, such as those obtained through MAM-induced microencephaly, did not drastically affect the pattern of Lot1 expression. In particular, Purkinje cells continued to show normal levels of immunoreactivity notwithstanding the altered cerebellar architecture. Primary cultures of cerebellar granule cells showed a temporal pattern of Lot1 expression resembling that of in vivo development, with mRNA and protein levels progressively decreasing with differentiation. When cerebellar granule cells were exposed to different neurotoxic challenges, Lot1 appeared not affected by purely apoptotic cell death, while transitorily induced by mixed necrotic-apoptotic cell death.     

Tottering mouse motor dysfunction is abolished on the Purkinje cell degeneration (pcd) mutant background

Tottering (tg) mice inherit a recessive mutation of the calcium channel alpha 1A subunit gene, which encodes the pore-forming protein of P/Q-type voltage-sensitive calcium channels and is predominantly expressed in cerebellar granule and Purkinje neurons. The phenotypic consequences of the tottering mutation include ataxia, polyspike discharges, and an intermittent motor dysfunction best described as paroxysmal dystonia. These dystonic episodes induce c-fos mRNA expression in the cerebellar circuitry, including cerebellar granule and Purkinje neurons, deep cerebellar nuclei, and the postsynaptic targets of the deep nuclei. Cellular abnormalities associated with the mutation include hyperarborization of brainstem nucleus locus ceruleus axons and abnormal expression of L-type calcium channels in cerebellar Purkinje cells. Here, the role of these two distinct neural pathways in the expression of tottering mouse intermittent dystonia was assessed. Lesion of locus ceruleus axons with the neurotoxin N-(2-chloroethyl)-N-ethyl-2-bromobenzyl-amine (DSP-4) did not affect the frequency of tottering mouse dystonic episodes. In contrast, removal of cerebellar Purkinje cells with the Purkinje cell degeneration (pcd) mutation by generation of tg/tg; pcd/pcd double mutant mice completely eliminated tottering mouse dystonia. Further, the c-fos expression pattern of tg/tg; pcd/pcd double mutants following restraint was indistinguishable from that of wild-type mice, suggesting that the pcd lesion eliminated an essential link in this abnormal neural network. These data suggest that the cerebellar cortex, where the mutant gene is abundantly expressed, contributes to the expression of tottering mouse dystonic episodes.     

Expression of Rho GTPases Rho-A and Rac1 in the adult and developing gerbil cerebellum

Rho GTPases proteins are essential for cytoskeletal reorganization and play important roles in the development of neuronal dendrites and axons. Several studies have implicated two members of the Rho GTPase family Rho-A and Rac1 activities in the neuronal polarization and the formation of axons and dendrites. In order to correlate cellular expressions of Rho-A and Rac1 with neuronal polarity (axons versus dendrite formation) in the central nervous system, the cerebellum and immunochemical techniques have been chosen. In the adult cerebellar cortex differential pattern of distribution between Rho-A and Rac1 was observed. While Rac1 expression was restricted to Purkinje cell (somata, dendrites and axons), Rho-A was ubiquitously distributed within the cerebellar cortex. Rac1 was localized in the Purkinje cell dendritic arborization (largest and tiny dendrites) and in their axons. This pattern of distribution was also observed during the postnatal development and followed the dendritic morphogenesis of Purkinje cell. Rho-A was highly expressed in the adult Purkinje cells somata, in cells of the granular layer, in glia within the white matter and in axons. Intense staining was observed in Bergmann glia cell bodies and processes. In the developing cerebellum, Rho-A was highly present in cells of the external and internal granule layers and in the Purkinje cell layer. Bergmann glia cell bodies and processes had the most intense staining during the development. The present study reveals a high expression of Rac1 and Rho-A during Purkinje cell neurites outgrowth period which occurred after birth in the cerebellum. In addition Rho-A is highly expressed in granule cell progenitor cells present in the external granular layer and therefore may play an important role in granule cell progenitor migration.     

Compartmentation of the mouse cerebellar cortex by neuronal calcium sensor-1

Neuronal calcium sensor-1 (NCS-1) is a member of the EF-hand calcium-binding protein superfamily, which is considered to modulate synaptic transmission and plasticity. The detailed distribution of NCS-1 was analyzed in the mouse cerebellar cortex. In coronal sections, the NCS-1 immunostaining displayed characteristic parasagittal banding pattern in the Purkinje cell layer and molecular layer, while there were no apparent bands in the granule cell layer. The alternating positively and negatively NCS-1-labeled Purkinje cell clusters contributed to this cerebellar compartmentation. In contrast, stellate-basket cells were uniformly NCS-1-positive throughout the cerebellum. Immunofluorescent double staining showed that NCS-1 and zebrin II exhibited a similar parasagittal banding pattern. Then, we performed mapping of NCS-1- and/or zebrin II-labeled Purkinje cell somata using seven sequential coronal sections. NCS-1-positive/zebrin II-positive Purkinje cell clusters were seen throughout the cerebellum, but NCS-1-positive/zebrin II-negative Purkinje cells were exceedingly rare. On the other hand, NCS-1-negative/zebrin II-positive Purkinje cell clusters were found in anterior lobule vermis and paraflocculus, whereas they were rarely seen in posterior lobules. The digitized quantitative analysis showed close relationship between NCS-1 and zebrin II immunoreactivity in the molecular layer. The correspondence between NCS-1 and zebrin II demonstrated here indicates a novel anteroposterior difference of cerebellar compartmentation and provides fundamental information of cerebellar organization.     

Cerebellar benzodiazepine receptors: cellular localization and consequences of neurological mutations in mice

The distribution of cerebellar [3H]flunitrazepam binding sites was studied autoradiographically in Purkinje cell degeneration (pcd/pcd), weaver (wv/wv), staggerer (sg/sg) and reeler (rl/rl) mutant mice. In the normal 78-day-old C57BL/6J mouse cerebellum, the highest concentration of [3H]flunitrazepam binding sites was observed over the molecular layer. Intermediate grain density was present over the Purkinje cell layer and intermediate to high density over the deep cerebellar nuclei. Low labeling was observed over the granule cell layer. Negligible concentrations of binding sites were seen in the white matter. In 45-49-day-old Purkinje cell degeneration mutants, where essentially all Purkinje cells have disappeared by day 45, there was a small decrease in grain density over the cerebellar cortex. Concomitantly, a substantial increase in grain density was observed over the deep cerebellar nuclei of the pcd/pcd mutants when compared to littermate controls. A significant increase in [3H]flunitrazepam labeling was observed over the cerebellar cortex of 81-86-day-old wv/wv mutants; this was most pronounced in the vermis where the granule cell loss was greatest. Over the hemispheres, where fewer granule cells degenerate, a lower density of binding sites was seen. Grain density over the wv/wv deep cerebellar nuclei was comparable to that of littermates. Substantially lower [3H]flunitrazepam labeling was detected over the cerebellar cortex of 25-27-day-old sg/sg mutants in which the number of granule, Purkinje and Golgi cells is greatly reduced; the labeling over the deep nuclei, however, was significantly increased. In 27-29-day-old rl/rl mutant cerebella, where all classes of cells are malpositioned, labeling density over all areas of the cerebellar cortex, including the Purkinje cell masses, was increased. Our autoradiographic data suggest that a proportion of cerebellar cortical benzodiazepine receptors are associated with Purkinje cells; we propose that the remainder of the receptors are localized on Golgi cells, while granule cells are devoid of receptors. In the deep cerebellar nuclei, the observed increase in benzodiazepine receptors in the pcd/pcd and sg/sg mutants may be a manifestation of denervation supersensitivity subsequent to the loss of innervation by Purkinje cell axon terminals. The finding of a high receptor density in the Purkinje cell masses of the rl/rl mutant, where Purkinje cells are devoid of afferent basket cell input, suggests that benzodiazepine receptors are expressed and maintained in the absence of a full complement of GABAergic afferents.     

Localization of ataxin-2 within the cerebellar cortex of the rat

Spinocerebellar ataxia type 2 is caused by a polyglutamine stretch in the protein ataxin-2 that is due to an expansion of a CAG repeat in the spinocerebellar ataxia-2 gene. The function of wild-type ataxin-2 has not been clarified. A widespread distribution of this protein throughout the brain has been reported. We examined the expression of ataxin-2 in cortical cerebellar cells of the adult rat. We performed a single label immunohistochemical study of ataxin-2 and a single label immunofluorescence study of ataxin-2 and zebrin on adjacent sections, to compare the distribution of the observed parasagittal band pattern. We also performed a double label immunofluorescence study of ataxin-2 and one of each parvalbumin, calbindin, and calretinin. Single label studies revealed that between 50% and 70% of the Purkinje cells express ataxin-2. The abundance of ataxin-2 was different between hemisphere and vermis, with a clear prevalence for the former. Furthermore, the distribution of ataxin-2-positive Purkinje cells showed a peculiar alternating parasagittal band pattern. Among the other cortical cerebellar cells only basket and granule cells showed ataxin-2 staining. Our dual label studies showed that about 50% of calbindin and more than 70% of parvalbumin-immunoreactive Purkinje cells were also labeled for ataxin-2. The uneven distribution of ataxin-2 expression in the Purkinje cell layer does not support the hypothesized link between ataxin-2 content and cell vulnerability. The differences in ataxin-2 expression among the cell types of cerebellar cortex, on the other hand, suggest a possible correlation between ataxin-2 content and cell function.     

The localization of GABAA receptors in mice with mutations affecting the structure and connectivity of the cerebellum

The distribution of cerebellar [3H]muscimol binding sites was studied autoradiographically in normal C57BL/6J mice and in the weaver, reeler, Purkinje cell degeneration and staggerer mutant mice. In the normal 79-day-old mouse cerebellum, the highest concentration of [3H]muscimol binding sites was observed in the granule cell layer. A much lower grain density was present over the Purkinje cell and molecular layers and negligible numbers of binding sites were seen over the deep cerebellar nuclei and white matter. A significant decrease in [3H]muscimol labeling was observed over the cerebellar cortex of the 81-86-day-old weaver mutant; this was most pronounced in the vermis where granule cell loss was the greatest. Over the hemispheres, where fewer granule cells degenerate, a higher density of binding sites remained. In the 27-29-old reeler cerebellum, where Purkinje cells are malpositioned, no labeling was seen over the deep Purkinje cell masses. In the quasi-normal superficial cortex, labeling density over the surviving granule cell layer was only slightly decreased. In the 54-57-day-old Purkinje cell degeneration mutant, where essentially all Purkinje cells have disappeared by day 45, a 29% decrease in grain density over the granule cell layer was observed, while labeling was still present in the molecular layer. Virtually no [3H]muscimol labeling was detected over any part of the cerebellar cortex of the 25-27-day-old staggerer mutant (which lacks parallel fiber-Purkinje cell synapses), although clusters of surviving granule cells were present in significant numbers in the lateral aspects of the cortex. Our autoradiographic data indicate that GABAA receptors are associated with granule cells in both the molecular and granule cell layers. Furthermore, our results raise the possibility that the maintenance of receptor levels may be dependent upon synaptic contacts between the granule cell and its main postsynaptic target, the Purkinje cell.     

Granule cell raphes in the cerebellar cortex of chicken and mouse

The cerebellar cortex of the chicken embryo contains parasagittal segments of Purkinje cells. At intermediate stages of development, cell-dense ribbons of migrating granule cells ("raphes") are found between the segments. The complementary pattern of granule cell raphes and Purkinje cell segments represents a basic scheme of cerebellar organization that coincides with the expression domains of various genes, such as cadherins, gene regulatory proteins, and ephrins and their receptors. We have recently found the raphe/segment pattern also in a mammalian species, the postnatal mouse. Like in the chicken, the parasagittal raphes of granule cells were observed at the boundaries of Purkinje cell segments that differentially express cadherins. The number and arrangement of the raphes in the different cerebellar lobules is roughly similar in both species. The raphe/segment pattern is thus more widely distributed in vertebrates than previously assumed.     

On the cellular localization of cerebellar muscarinic receptors: An autoradiographic analysis of weaver, reeler, purkinje cell degeneration and staggerer mice

Light microscopic autoradiography of [3H]quinuclidinyl benzilate binding sites was used to study the distribution of muscarinic cholinergic receptors in mouse mutants which have abnormalities affecting specific cerebellar cell types. In the normal C57BL/6J mouse, binding sites were distributed throughout the cerebellar cortex, with the highest levels in the granule cell layer and deep cerebellar nuclei. Normal binding site density was observed in the cerebellum of the weaver mutant in which the majority of granule cells had degenerated. The density of [3H]quinuclidinyl benzilate binding sites was elevated in the cortex of the reeler, despite a reduction in the number of granule cells. The concentration of binding sites was also high over the Purkinje cell masses where granule cells were largely absent. No significant reduction in cortical [3H]quinuclidinyl benzilate binding site density was detected in the Purkinje cell degeneration mutant, in which essentially all Purkinje cells had degenerated. In contrast, receptor binding in the deep cerebellar nuclei of this mutant was significantly increased. A substantial increase in labeling was observed in the cortex and deep nuclei of the staggerer cerebellum in which a large fraction of Golgi II cells, Purkinje cells, granule cells and mossy fibers have degenerated. We discuss the possibility that the persistence of [3H]quinuclidinyl benzilate binding sites in all four mutants may imply a non-neuronal localization for a large proportion of muscarinic receptors in the mouse cerebellar cortex.     

Expression of proenkephalin mRNA in developing cerebellar cortex of the rat: expression levels coincide with maturational gradients in Purkinje cells.

The cellular localization of proenkephalin (PE) mRNA expression was systematically examined in midsagittal (vermal) sections of the developing rat cerebellar cortex by in situ hybridization. PE mRNA was initially detected in Golgi cells of postnatal day 7 (PND 7) rats and in each group thereafter. Moreover, PND 7 rats also displayed an intense layer of PE mRNA hybridization signal over the Purkinje cell layer. By PND 14, distinct cellular labeling was observed in a subpopulation of Purkinje cells in all lobules of the vermis except lobule III. At PND 7 and 14, the area and level of intensity of Purkinje cell associated PE mRNA hybridization signal followed a gradient that was most intense caudally but then decreased rostrally. At PND 21, the proportion of labeled Purkinje cells and the intensity of PE hybridization signal was evenly dispersed between the anterior and posterior lobules of the cerebellar vermis. PE hybridization signal was not detected in the developing neural cells of the external granular layer or the interneurons of the molecular layer in the vermis. These results indicate that the ontogeny of PE mRNA expression in Purkinje cells is developmentally regulated since levels of expression closely follow the chronological order of settling and maturation of these neurons. Based on prior evidence that endogenous opioids inhibit the growth of Purkinje cell dendrites and dendritic spines, PE expression is likely to be important for Purkinje cell maturation.     

Differential expression of brain-derived neurotrophic factor,neurotrophin-3, and low-affinity nerve growth factor receptor during the postnatal development of the rat cerebellar system

The spatio-temporal pattern of expression of neurotrophin-3 (NT3), brain-derived neurotrophic factor (BDNF) and low-affinity nerve growth factor receptor (LNGFR) genes was analyzed in the postnatal developing cerebellar system of the rat by in situ hybridization histochemistry. Different ontogenetic patterns of expression were observed for these three genes. In agreement with previously published results (Neuron, 5 (1990) 501–509; Dev. Brain Res., 55 (1990) 288–292) we found that NT3 and LNGFR mRNA peaked early, during the first 2 postnatal weeks, whereas BDNF mRNA peaked later, around postnatal day 20, in the cerebellar cortex. High levels of NT3 mRNA were found in the internal granule cell layer as early as postnatal day 5. NT3 mRNA was also present in the external-premigratory granule cell layer at postnatal day 10. From postnatal day 5 on, LNGFR mRNA was present in the proliferative area of the external granule cell layer and in the Purkinje cells. NT3 mRNA level decreased and BDNF mRNA increased in granule cells concomitantly with their migration and maturation, suggesting a sequential stimulation of these two genes during this developmental process. LNGFR mRNA levels decreased along the same period. Although practically undetectable in the cerebellar granule cell layer in the first two postnatal weeks, BDNF mRNA was transiently expressed in the deep cerebellar nuclei during this time and it was very abundant in the inferior olivary system from postnatal day 5 on. LNGFR mRNA was transiently expressed in the inferior olivary system, in the first postnatal week. These data are discussed in relation to the coordinated postnatal maturation of the different cells of the cerebellar system. Our results are compatible with a local delivery and role of NT3 in the early postnatal development of the cerebellar cortex. Its presence may be involved in the process of granule cell migration and/or the establishment of early synaptic contacts. BDNF, on the contrary, could play a role at a later stage, perhaps as a maintenance factor.     

Carbonic anhydrase II and carbonic anhydrase-related protein in the cerebellar cortex of normal and lurcher mice

The developmental profiles of carbonic anhydrase II (CA-II) and a carbonic anhydrase related protein (CARP) were studied in rat and mouse cerebella. Enzyme histochemistry, immunohistochemistry, in situ hybridisation and Western blotting were used to study the synthesis and expression of these enzymes in cerebellar sections from age matched control, CA-II deficient and lurcher mice, the latter being characterised by Purkinje cell degeneration. Both CA-II and CARP were first found to be expressed in the Purkinje cells in the 9 day old mouse, and the immunoreactivity of both peptides increased with time. Immunohistochemistry showed more intense staining of CARP than of CA-II in Purkinje cells throughout the developmental profile of the mouse, and this was mirrored by the mRNA levels determined by in situ hybridisation. Immunohistochemistry of CA-II and CARP also demonstrated the progressive dendritic growth of the mouse and rat Purkinje cells. CA-II and CARP immunoreactivity ceased by the end of cerebellar maturation. The onset of Purkinje cell degeneration was detected at day 10 in the lurcher mouse, with concomitant marked decrease in CA-II level: however CARP expression was found to be unchanged. By postnatal day 16 neither CA-II mRNA, protein, nor activity was detectable in contrast to CARP which remained at a decreased level until the Purkinje cell population had completely degenerated. Our findings suggest a role of CA-II in the degenerative processes of the lurcher Purkinje cells, with CARP playing an important role in the development and maturation of the cerebellar cortex.     

Aging of the human cerebellum: a stereological study

Cerebella from 19 normal Caucasian males, ages 19-84 years, were studied using stereological methods. Cerebellum was divided into four different regions: the anterior and posterior lobe, the vermis, and the flocculonodular lobe. Total volume of the cerebellar cortex and white matter, cerebellar surface area, total Purkinje and granule cell number, and the distribution of the volumes of the Purkinje cells and their nuclei were estimated in all four regions. The global white matter was reduced by 26% with age; the mean volume of the Purkinje cell body was decreased by 33% with no decrease in the volume of the Purkinje cell nuclei. A tendency towards a 16% total cerebellar volume loss was seen without a concomitant neuron loss. No global Purkinje or granule cell loss was detected with age, total Purkinje cell number being 28 x 10(6) (coefficient of variation, CV = 0.16) and total granule cell number 109 x 10(9) (CV = 0.17). However, a significant change was observed with age in the anterior lobe, where a selective 40% loss of both Purkinje and granule cells was found. Furthermore, a 30% loss of volume, mostly due to a cortical volume loss, was recorded in the anterior lobe, which is predominantly involved in motor control.