Immunocytochemical Localization of Chondroitin and Chondroitin 4- and 6-Sulfates in Developing Rat Cerebellum

Monoclonal antibodies specific for unsulfated, 4-sulfated, and 6-sulfated disaccharide "stubs" that remain attached to the core protein after chondroitinase ABC digestion of chondroitin/dermatan sulfate proteoglycans have been used to study the localization of chondroitin and the two isomeric chondroitin sulfates in developing rat cerebellum. At 1-2 weeks postnatal, unsulfated chondroitin is present in the granule cell layer, molecular layer, and prospective white matter, but there was no staining of the external granule cell layer other than light staining of Bergmann glia fibers. By 3 weeks postnatal, staining of the molecular layer has disappeared and has diminished in the white matter, whereas in adult cerebellum only the granule cell layer remains stained. The staining pattern of chondroitin 4-sulfate is similar to that for chondroitin at 1-2 weeks postnatal, but in contrast to chondroitin, chondroitin 4-sulfate increases in the molecular layer at 3 weeks, and this becomes the most densely stained region of adult cerebellum. Chondroitin 6-sulfate is present predominantly in the prospective white matter of 1-2 week postnatal cerebellum, although significant staining of the granule cell layer is also seen. By 3 weeks postnatal the granule cell staining of chondroitin 6-sulfate has decreased, and in adult cerebellum staining is seen only in the white matter and to a lesser extent in the granule cell layer. Electron microscopy confirmed the presence of chondroitin sulfate in the cytoplasm of neurons and glia of adult brain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Light and electron microscopic studies on the localization of hyaluronic acid in developing rat cerebellum

The hyaluronic acid-binding region was prepared by trypsin digestion of chondroitin sulfate proteoglycan aggregate from the Swarm rat chondrosarcoma, and biotinylated in the presence of hyaluronic acid and link protein. After isolation by gel filtration and HPLC in 4 M guanidine HCl, the biotinylated hyaluronic acid-binding region was used, in conjunction with avidin-peroxidase, as a specific probe for the light and electron microscopic localization of hyaluronic acid in developing and mature rat cerebellum. At 1 w postnatal, there is strong staining of extracellular hyaluronic acid in the presumptive white matter, in the internal granule cell layer, and as a dense band at the base of the molecular layer, surrounding the parallel fibers. This staining moves progressively towards the pial surface during the second postnatal week, and extracellular staining remains predominant through postnatal week three. In adult brain, there is no significant extracellular staining of hyaluronic acid, which is most apparent in the granule cell cytoplasm, and intra-axonally in parallel fibers and some myelinated axons. The white matter is also unstained in adult brain, and no staining was seen in Purkinje cell bodies or dendrites at any age. The localization of hyaluronic acid and its developmental changes are very similar to that previously found in immunocytochemical studies of the chondroitin sulfate proteoglycan in nervous tissue (Aquino, D. A., R. U. Margolis, and R. K. Margolis. 1984. J. Cell Biol. 99:1117-1129; Aquino, D. A., R. U. Margolis, and R. K. Margolis. J. Cell Biol. 99:1130-1139), and to recent results from studies using monoclonal antibodies to the hyaluronic acid-binding region and link protein. The presence of brain hyaluronic acid in the form of aggregates with chondroitin sulfate proteoglycans would be consistent with their similar localizations and coordinate developmental changes.     

Immunohistochemical Localization of α-Mannosidase During Postnatal Development of the Rat Cerebellum

The localization of alpha-D-mannosidase in the rat cerebellum was studied by using indirect immunohistochemistry at both optical and electron microscopic levels. In the adult the enzyme is particularly concentrated in the dendrites and cell bodies of Purkinje cells, basket cells, and Golgi neurons in the cerebellar cortex and in the cytoplasm and dendrites of deep nuclei neurons. The cytoplasm of granule cells is poorly stained, whereas parallel fibers, white matter, Bergman fibers, and Golgi epitheloid cell perikarya show virtually no staining. Electron microscopy suggests that most of the staining is found in the cytosol, although some staining is found in the postsynaptic densities of the synapses between parallel fibers and Purkinje dendrites. The pattern of staining was followed throughout the postnatal development of the rat cerebellum. At bith an intense and diffuse staining is found in all cells except those of the external germinative layer. At the 6th postnatal day, Purkinje cell bodies and apical cones are strongly labeled. From the 13th day on the pattern is very similar to that found in the adult. However, at the 18th postnatal day (when compared with the other structures), the staining of Purkinje cell dendrites seems to be higher than at all other ages. These data are correlated with biochemical studies and discussed in relation to the possible role of this enzyme during the postnatal development of the rat cerebellum.     

Monoclonal antibody (M2) to glial and neuronal cell surfaces

A monoclonal antibody designated M2 arose from the fusion of mouse myeloma cells with splenocytes from a rat immunized with particulate fraction from early postnatal mouse cerebellum. Expression of M2 antigen was examined by indirect immunofluorescence on frozen sections of developing and adult mouse cerebellum and on monolayer cultures of early postnatal mouse cerebellar cells. In adult cerebellum, M2 staining outlines the cell bodies of granule and Purkinje cells. A weaker, more diffuse staining is seen in the molecular layer and white matter. In sections of newborn cerebellum, M2 antigen is weakly detectable surrounding cells of the external granular layer and Purkinje cells. The expression of M2 antigen increases during development in both cell types, reaching adult levels by postnatal day 14. At all stages of postnatal cerebellar development, granule cells that have completed migration to the internal granule layer are more heavily stained by M2 antibodies than are those before and in process of migration. In monolayer cultures, M2 antigen is detected on the cell surface Of all GFA protein-positive astrocytes and on more immature oligodendrocytes, that express 04 antigen but not 01 antigen. After 3 days in culture, tetanus toxinpositive neurons begin to express M2 antigen. The same delayed expression of M2 antigen on neurons is observed in cultures derived from mice ranging in age from postnatal day 0 to 10.     

An immunohistochemical analysis of rat hippocampal antigens in early postnatal ontogeny by using monoclonal antibodies]

In order to study the molecular mechanisms of neurogenesis, monoclonal antibodies (MAbs) were produced against antigens of the developing rat hippocampus. MAb 3G7-F8 was used for immunohistochemical localization of the corresponding antigen of paraffin sections of the rat brain at days 0, 5, 14, and 21 of the postnatal development. In the hippocampus of newborn and 5-day-old rats, positive immunostaining was observed in the cytoplasm and proximal segments of processes of neurons located in granular, polymorph, and pyramidal layers, as well as in entorhinal cortex. In granule cell bodies and neurons of entorhinal cortex specific staining decreased by day 14 and disappeared by day 21 after birth, whereas neurons of pyramidal and polymorph layers remained immunopositive. Diffuse specific staining in the cerebellum was observed beginning from day 5 after birth in the Purkinje cell layer. On days 14-21 positive reaction was observed in Purkinje cell bodies and in the layer containing dendrites of Purkinje cells and parallel fibers. External and internal granular layers remained immunonegative. No specific staining was observed in other regions of the brain, as well as in the control slices. These data suggest that the antigen detected by the 3G7-F8 antibody is involved in the formation of the neuronal connections.     

Immunolocalization of the acid-sensing ion channel 2a in the rat cerebellum

The acid-sensing ion channels (ASICs) are members of the DEG/ENaC superfamily of Na+ channels. Acid-gated cation currents have been detected in neurons from multiple regions of the brain including the cerebellum, but little is known about their molecular identity and function. Recently, one of ASICs (ASIC1a) was implicated in synaptic plasticity. In this study we examined the subcellular distribution of ASIC2a in rat cerebellum by immunostaining and confocal microscopy. Monoclonal antibodies for labeling of defined brain structures, for example, astroglia, Purkinje cell dendrites, nuclei, and presynaptic terminals were used for colocalization analyses. In the gray matter, the anti-ASIC2a antibody intensively stained dendrite branches of Purkinje cells evenly distributed throughout the entire molecular layer (ML). In the granule cell layer (GL), anti-ASIC2a antibody stained synaptic glomeruli. Neuronal localization of ASIC2a was confirmed by lack of co-staining with glial fibrillary acidic protein. Anti-ASIC2a staining in the ML colocalized with metabotropic glutamate receptor 1alpha (mGluR1alpha) in Purkinje cell dendrites and dendritic spines. Both proteins, mGluR1alpha and ASIC2a, were enriched in a crude synaptic membrane fraction prepared from cerebellum, suggesting synaptic expression of these proteins. Dual staining with anti-syntaxin 1A and anti-ASIC2a antibodies demonstrates characteristic complementary distribution of two proteins in both ML and GL. Because syntaxin 1A localized in presynaptic membranes and synaptic vesicles, complementary distribution with ASIC2a suggests postsynaptic localization of ASIC2a in these structures. This study shows specific localization of ASIC2a in both Purkinje and granule cell dendrites of the cerebellum and enrichment of ASIC2a in a crude cerebellar synaptic membrane fraction. The study is the first report of synaptic localization of ASIC2a in the CNS. The synaptic localization of ASIC2a in the cerebellum makes this channel a candidate for a role in motor coordination and learning.     

Expressions of amyloid precursor protein, synaptophysin and presenilin-1 in the different areas of the developing cerebellum of rat

This study reveals the expressions of Alzheimer's disease-related amyloid precursor protein, presenilin-1, and a presynaptic marker protein, synaptophysin, in the archi-, paleo- and neocerebellum during the postnatal development of the rat. The Western blot results demonstrate a gradual increase in the soluble amyloid precursor protein level in the archicerebellum during the first 3 weeks, while in the neo- and paleocerebellum the levels reach a plateau as early as the 1st week. Immunohistochemically, the protein is present in the deep part of the external granule cell layer and the internal granule cell layer in the newborn animal, while in 3-week-old animals the staining appears mainly in the perikarya and dendrites of the Purkinje cells. The level of synaptophysin increases progressively from postnatal day 7 up to 3 weeks in the archi- and paleocerebellum, and up to 6 weeks in the neocerebellum. Immunohistochemically, the amyloid precursor protein staining appears first in the inner part of the molecular layer and in the internal granule cell layer. In a 3-week-old animal, synaptophysin staining is present in all areas of the cerebellar molecular layer and in the internal granule cell layer. The presenilin-1 immunohistochemical reaction appeared equally in the archi-, paleo- and neocerebellum. Much of the staining is present in the glial cells and Purkinje cells. Less immunoreactivity is observed in the Golgi cells and granule cells. It is concluded that the postnatal expressions of soluble and membrane-bound amyloid precursor protein, synaptophysin and presenilin-1 are regulated differently during the ontogenetical development of the archi-, paleo- and neocerebellum of rat. Further, the amyloid precursor protein and presenilin-1 may be present in cells which do not degenerate in Alzheimer's disease.     

Immunocytochemical localization of a chondroitin sulfate proteoglycan in nervous tissue. II. Studies in developing brain

In contrast to the intracellular (cytoplasmic) localization of chondroitin sulfate proteoglycans in adult brain (Aquino, D. A., R. U. Margolis, and R. K. Margolis, 1984, J. Cell Biol. 99:940-952), immunoelectron microscopic studies in immature (7 d postnatal) rat cerebellum demonstrated almost exclusively extracellular staining in the granule cell and molecular layers. Staining was also extracellular and/or associated with plasma membranes in the region of the presumptive white matter. Axons, which are unmyelinated at this age, generally did not stain, although faint intracellular staining was present in some astrocytes. At 10 and 14 d postnatal there was a significant decrease in extracellular space and staining, and by 21 d distinct cytoplasmic staining of neurons and astrocytes appeared. This intracellular staining further increased by 33 d so as to closely resemble the pattern seen in adult brain. Analyses of the proteoglycans isolated from 7-d-old and adult brain demonstrated that they have essentially identical biochemical compositions, immunochemical reactivity, size, charge, and density. These findings indicate that the antibodies used in this study recognize the same macromolecule in both early postnatal and adult brain, and that the localization of this proteoglycan changes progressively from an extracellular to an intracellular location during brain development.     

GAP-43，Netrin-1，Collapsin-1和Neuropilin-1在出生后小鼠小脑中的动态表达

GAP-43,netrin-1,collapsin-1和neuropilin-1被认为在成网络分布的神经联系中发挥重要的作用．在年幼的啮齿类动物中,小脑包含5种不同的集中分布层：白质、内颗粒细胞层(IGL)、浦肯野氏细胞层(PCL)、分子层(ML)和外颗粒细胞层(EGL)．与浦肯野氏神经元在出生前产生这一点不同的是,EGL中的细胞在出生后产生,它们接受从前脑olivary核团发出的攀援纤维的主要神经投射,以及从内颗粒细胞发出的平行纤维的神经投射．这些神经投射主要在出生后的前3个星期内建立,同时还有浦肯野氏细胞的发育和成熟．而GAP-43,netrin-1,collapsin-1和neuropilin-1在出生后小脑发育的潜在作用仍然不清楚．为了更加清楚地探讨上述问题,检验了GAP-43,netrin-1,collapsin-1和neuropilin-1的mRNA与蛋白质在出生后5,10,20天和成年小鼠小脑中的表达情况．研究结果显示,这4种分子在小鼠出生后的小脑中有不同的时间和空间表达形式,这些结果与出生后发育和成年期间的轴突发生、延伸以及突触形成都有关联．通过免疫组织化学双标染色,发现小鼠出生后10天的小脑中,GAP-43阳性的浦肯野氏细胞也显示netrin-1或collapsin-1阳性,并且collapsin-1阳性的细胞也对 netrin-1 阳性．上述研究结果证明这4种分子可能参与了小脑的出生后发育．     

Cloning and localization of the cGMP-specific phosphodiesterase type 9 in the rat brain

In this study, we report the cloning of the rat cGMP-specific phosphodiesterase type 9 (PDE9A) and its localization in rat and mouse brain by non-radioactive in situ hybridization. Rat PDE9A was 97.6% identical to mouse PDE9A1 and showed 92.1% similarity on the amino acid level to the human homologue. PDE9A mRNA was widely distributed throughout the rat and mouse brain, with the highest expression observed in cerebellar Purkinje cells. Furthermore, strong staining was detected in areas such as cortical layer V, olfactory tubercle, caudate putamen and hippocampal pyramidal and granule cells. Comparison of PDE9A mRNA expression by double staining with the cellular markers NeuN and glial fibrillary acidic protein demonstrated that PDE9A expression was mainly detected in neurons and in a subpopulation of astrocytes. Using cGMP-immunocytochemistry, the localization of cGMP was investigated in the cerebellum in which the highest PDE9 expression was demonstrated. Strong cGMP immunoreactivity was detected in the molecular layer in the presence of the non-selective PDE inhibitor 3-isobutyl-1-methylxanthine (IBMX). After treatment with soluble guanylyl cyclase activators the granular layer also showed cGMP staining, whereas no clear immunostaining was detected in Purkinje cells under all conditions investigated, which might be due to the presence of the IBMX-insensitive PDE9A in these cells. The present findings indicate that PDE9A is highly conserved between species and is widely distributed throughout the rodent brain. PDE9A is probably involved in maintenance of low cGMP levels in cells and might play an important role in a variety of brain functions involving cGMP-mediated signal transduction.     

Postnatal expression of Doublecortin (Dcx) in the developing cerebellar cortex of mouse

We have investigated the expression of Doublecortin (Dcx) protein in the developing cerebellum of mouse from postnatal 2nd day to postnatal 22nd day and in young adults by immunohistochemistry. Strong expression of Dcx was present in the inner zone of the external granule cell layer, and remained strong while postmitotic granule cell precursors were present in this transitory layer. Descending granule cell precursors exhibited Dcx immunostaining not only while migrating but for a short time also after their settlement. Dcx-immunostained cells appeared in deep cerebellocortical territories and in the cerebellar white matter during the first postnatal week. These bipolar cells were arranged in the sagittal plane and built up transitory migratory streams during the second postnatal week and their number gradually decreased during the third postnatal week. Upward migration of bipolar cells was observed while leaving the migratory streams, penetrating the internal granule cell layer and the molecular layer. These cells were considered as precursors of late migrating molecular layer interneurons. However, a proportion of Dcx-immunostained cells underwent a bipolar-to-multipolar dendritic remodellation and - on the basis of strong morphological similarities - was taken for "multipotent progenitor cells", described recently in the neocortex of adult rat.     

Localisation of the MRC OX-2 Glycoprotein on the Surfaces of Neurones

The MRC OX-2 monoclonal antibody recognises membrane glycoproteins of Mr 41,000 in rat brain and 47,000 on thymocytes. It also reacts with follicular dendritic cells in lymphoid organs, endothelium, smooth muscle, and B-lymphocytes. Indirect immunoperoxidase staining of cryostat sections showed that OX-2 antigen was present throughout the cerebellum, with staining of both grey and white matter. Blood vessels were also stained. The Purkinje cell layer appeared to be unlabelled. Double-immunofluorescence staining of cerebellar interneurone cultures with MRC OX-2 antibody and tetanus toxin showed that all tetanus-positive cells (neurones) were MRC OX-2-positive. Glial fibrillary acidic protein-positive astrocytes were not labelled by MRC OX-2 antibody. Thus OX-2 antigen is one of the few biochemically characterised components of neuronal membranes and its properties are compared with those of the neuronal membrane glycoprotein Thy-1.     

Electron microscopic localization of neuron-specific enolase in rat and mouse brain

The cellular distribution and intracellular localization of neuron-specific enolase (NSE) has been studied by electron microscopic immunocytochemistry in the brain of the rat and of the mouse. Although the intensity of staining was less in the mouse, the same structures were positive in both species. In the cerebrum, the neuronal perikarya and dendrites were intensely stained, but staining was almost entirely absent in the presynaptic terminals. The deep neurons of the brain stem were also positive. In the cerebellum, perikarya, axons, and parallel fibers of the granule cell neurons were stained as were the synaptic vesicles and presynaptic membranes of the synapses between the parallel fibers and the Purkinje cell dendrites. Golgi cell dendrites, basket cells and their axons, and mossy fibers were also positive. In contrast, the Purkinje cells including their dendrites, and the climbing fibers that formed synapses with the Purkinje cell dendrites were not stained. The majority of the myelinated axons in both the cerebrum and the cerebellum did not stain, but the fibrillary astrocytic processes between myelinated axons in the white matter did. Oligodendroglia, protoplasmic astrocytes, Bergmann glia, astrocytes investing capillaries, and vascular endothelial cells were negative for reaction product. In the positively staining cells and their processes, the positivity was dispersed throughout the cytoplasm and corresponded most closely to the distribution of ribosomes, the granular endoplasmic reticulum, and microtubules. Nuclei, mitochondria, the cisternae of the Golgi complex, myelin lamellae, and most membranes were not stained.     

Characterization of Annexins in Mammalian Brain

Three annexins--p68, endonexin, and p32--have been isolated from porcine brain using their calcium-dependent affinity for membranes. Large amounts (20-50 mg/kg of tissue) of p68 and p32 can be isolated from cerebrum and cerebellum. The p68 is present as up to 0.3% of total porcine brain protein. The p68 and p32 from porcine brain bind to phosphatidic acid (half-maximal binding at 6 and 34 microM free calcium, respectively) and to phosphatidylserine (8 and 34 microM, respectively). They do not bind to phosphatidylcholine at calcium concentrations up to 1 mM. Two other major proteins (Mr 180,000 and Mr 76,000) were isolated with the annexins in a calcium-dependent manner but do not bind to phospholipids. The 180-kilodalton protein is the heavy chain of clathrin. From immunohistochemical studies, p68 is strongly associated with the plasma membranes of Purkinje cell bodies and dendrites in porcine cerebellum. It is also an intracellular component of Purkinje cells localized to perinuclear structures. Staining of axons in the white matter and granule cell layer was also seen. In contrast, p32 is completely absent from Purkinje cells and their dendrites; it is predominantly located in the molecular layer and in white matter of the cerebellar folds. The distribution of p32 may be consistent with a predominantly glial localization.     

Localization of 4.1 related proteins in cerebellar neurons

Localization of 4.1 related proteins in neurons was studied with immunofluorescence microscopy and with immunoelectron microscopy on ultrathin cryosections. In rat cerebellum, 4.1 immunoreactive proteins were demonstrated in Purkinje cell bodies, dendrites and other neurons in the cerebellar cortex. Some glial cells showed staining, but no labeling was found in myelinated axons of the white matter and of the glomeruli in the granule cell layer. At the ultrastructural level, the 4.1 related proteins were localized mainly in the cytoplasmic matrix, while some labeling was found underneath the plasma membrane. To determine whether 4.1 related proteins in neuronal cytoplasm exist as part of the cytoskeleton or not, PC12 cells cultured in the presence of nerve growth factor were stained with the anti-4.1 antibody. Since cytoplasmic staining was retained after detergent treatment, the 4.1 related proteins seem to exist as a component of the neural cell cytoskeleton. Localization of 4.1 related proteins during the postnatal development of the cerebellum was also studied. In Purkinje cells, localization of 4.1 related proteins changed according to the stages of the postnatal development. The present data suggest that 4.1 related proteins in neurons localized mainly in the cytoplasm and may play some role in organizing cytoskeletal networks in the cytomatrix. Their distribution is developmentally regulated in some neurons, possibly in relationship to their maturation in the cytoskeleton.     

Purification of mouse brain (Na+ + K+)-ATPase catalytic unit, characterization of antiserum, and immunocytochemical localization in cerebellum, choroid plexus, and kidney

The denatured catalytic polypeptide of mouse brain (Na+ + K+)-adenosine triphosphatase(ATPase) was separated from microsomal membranes on polyacrylamide gels and used as an immunogen. The antiserum, characterized by immunoblots, recognizes the polypeptide corresponding to the catalytic unit in various fractions of mouse brain and cross-reacts with the catalytic unit from lamb kidney, duck salt gland, and electroplax. The same polypeptide in brain and salt gland is recognized by antiserum raised against purified lamb kidney enzyme. Light microscopy was performed with the peroxidase-conjugated second antibody method. In mouse cerebellum, immunochemical staining outlines Purkinje cell and granule cell perikarya. Intense activity is associated with regions of high synaptic content including the pericellular basket meshes and preaxonal regions of Purkinje cells and the glomeruli in the granular layer. In the molecular layer, the neuropil is diffusely reactive with distinct vertically oriented processes evident. White matter exhibits light stain deposition. Choroid plexus presents abundant reaction product only at ependymal apical surfaces, while the ependymal lining of the fourth ventricle displays little or no immunoreactivity. Specificity of the antiserum was demonstrated further in mouse kidney where staining conforms to the well-characterized localization of the enzyme along basolateral surfaces of cortical and medullary tubules. The biochemical and immunocytochemical data show the efficacy of generating antisera to brain (Na+ + K+)-ATPase using catalytic polypeptide as an immunogen.     

Axonal Membrane-Skeletal Protein A60: Association with a Brain Spectrin-Binding Activity and Entry into Cerebellar Axons at a Stage After the Initiation of Axonal Growth

Abstract: A60 is a 60-kDa component of the axonal cortical cytoskeleton in CNS neurones. It appears to be neurone specific and is tightly bound to brain membranes. In this study the cytoskeletal activities and developmental expression of A60 in rat cerebellum have been examined using the monoclonal antibody DR1. A60 in a partially purified soluble extract of brain membranes interacts selectively with brain but not erythrocyte spectrin. Because erythrocyte spectrin is more closely related to the dendritic form of spectrin than the axonal form, this raises the possibility that AGO localises in axons by interaction with the axonal form of spectrin only. A60 is not found in rat cerebellum before the day of birth. However, during postnatal development of the cerebellum (days 1–13) DR1 reactivity appears progressively. On postnatal day 1, a small population of cells in the mantle layer (presumptive Purkinje cells) is DR1 positive. There is no DR1 reactivity found in Purkinje cell axons during their initial phase of growth. By postnatal day 7, Purkinje cell bodies, initial dendritic segments, and the cerebellar white matter are all positive. This pattern of labelling is strengthened up until postnatal day 13. By contrast, in adult rat cerebellum, the location of A60 has changed so that it is most concentrated in axons, and dendritic staining is lost. These data indicate that A60 is a spectrin-binding component of the adult axonal membrane skeleton, the presence of which is only required in axons after the initial phase of growth.     

Changes in TRPC channel expression during postnatal development of cerebellar neurons

In the brain, classical (canonical) transient receptor potential (TRPC) channels are thought to be involved in different aspects of neuronal development. We investigated the developmental expression profile of TRPC channels in rat cerebellum during the first 6 weeks after birth. TRPC3 expression is significantly up-regulated whereas TRPC4 and TRPC6 expression are significantly down-regulated over this period of time. TRPC3 expression is mainly found on Purkinje cells and their dendrites, suggesting that the increase in TRPC3 expression reflects development of the dendritic tree of Purkinje cells. TRPC4 expression was restricted to granule and their precursor cells. TRPC6 expression is found on Purkinje cell bodies, on mature granule cells in the internal granule cell layer (but not their precursors) and interneurons in the molecular layer. The decrease in TRPC4 expression suggests that it is required for proper granule cell development whereas the decrease in TRPC6 expression is presumably correlated with interneuron development. Moreover, we demonstrate the presence of functional TRPC channels on Purkinje cell dendrites that are activated following stimulation of metabotropic glutamate receptors. Our results reveal cell-specific expression patterns for different TRPC proteins and suggest that developmental changes in TRPC protein expression may be required for proper postnatal cerebellar development.     

Immunocytochemical Localization of TASK-3 Protein (K2P9.1) in the Rat Brain

Among all K2P channels, TASK-3 shows the most widespread expression in rat brain, regulating neuronal excitability and transmitter release. Using a recently purified and characterized polyclonal monospecific antibody against TASK-3, the entire rat brain was immunocytochemically analyzed for expression of TASK-3 protein. Besides its well-known strong expression in motoneurons and monoaminergic and cholinergic neurons, TASK-3 expression was found in most neurons throughout the brain. However, it was not detected in certain neuronal populations, and neuropil staining was restricted to few areas. Also, it was absent in adult glial cells. In hypothalamic areas, TASK-3 was particularly strongly expressed in the supraoptic and suprachiasmatic nuclei, whereas other hypothalamic nuclei showed lower protein levels. Immunostaining of hippocampal CA1 and CA3 pyramidal neurons showed strongest expression, together with clear staining of CA3 mossy fibers and marked staining also in the dentate gyrus granule cells. In neocortical areas, most neurons expressed TASK-3 with a somatodendritic localization, most obvious in layer V pyramidal neurons. In the cerebellum, TASK-3 protein was found mainly in neurons and neuropil of the granular cell layer, whereas Purkinje cells were only faintly positive. Particularly weak expression was demonstrated in the forebrain. This report provides a comprehensive overview of TASK-3 protein expression in the rat brain.     

Mouse Model Reveals the Role of RERE in Cerebellar Foliation and the Migration and Maturation of Purkinje Cells

Nuclear receptors and their coregulators play a critical role in brain development by regulating the spatiotemporal expression of their target genes. The arginine-glutamic acid dipeptide repeats gene (Rere) encodes a nuclear receptor coregulator previously known as Atrophin 2. In the developing cerebellum, RERE is expressed in the molecular layer, the Purkinje cell layer and the granule cell layer but not in granule cell precursors. To study RERE''s role in cerebellar development, we used RERE-deficient embryos bearing a null allele (om) and a hypomorphic allele (eyes3) of Rere (Rere ^om/eyes3). In contrast to wild-type embryos, formation of the principal fissures in these RERE-deficient embryos was delayed and the proliferative activity of granule cell precursors (GCPs) was reduced at E18.5. This reduction in proliferation was accompanied by a decrease in the expression of sonic hedgehog (SHH), which is secreted from Purkinje cells and is required for normal GCP proliferation. The maturation and migration of Purkinje cells in Rere ^om/eyes3 embryos was also delayed with decreased numbers of post-migratory Purkinje cells in the cerebellum. During the postnatal period, RERE depletion caused incomplete division of lobules I/II and III due to truncated development of the precentral fissure in the cerebellar vermis, abnormal development of lobule crus I and lobule crus II in the cerebellar hemispheres due to attenuation of the intercrural fissure, and decreased levels of Purkinje cell dendritic branching. We conclude that RERE-deficiency leads to delayed development of the principal fissures and delayed maturation and migration of Purkinje cells during prenatal cerebellar development and abnormal cerebellar foliation and Purkinje cell maturation during postnatal cerebellar development.