Discoidin domain receptor 1 functions in axon extension of cerebellar granule neurons

In the developing cerebellum, granule neuron axon outgrowth is a key step toward establishing proper connections with Purkinje neurons, the principal output neuron of the cerebellum. During a search for genes that function in this process, we identified a receptor tyrosine kinase discoidin domain receptor 1 (DDR1) expressed in granule cells throughout their development. Overexpression of a dominant-negative form of DDR1 in immature granule cells results in severe reduction of neurite outgrowth in vitro, in dissociated primary culture, and in vivo, in organotypic slices of neonatal cerebellum. Granule cells that fail to extend axons are positive for differentiation markers such as TAG-1 and the neuron-specific class III beta-tubulin, suggesting that development is affected after granule cells commit to terminal differentiation. DDR1 activation appears to be mediated by its ligand, collagen, which is localized to the pial layer of the developing cerebellum, thereby leading to granule cell parallel fiber extension. Our results therefore indicate that collagen-DDR1 signaling is essential for granule neuron axon formation and further suggest a unique role of pia in cerebellar cortex histogenesis.     

The transmembrane semaphorin Sema6A controls cerebellar granule cell migration

The transmembrane semaphorin protein Sema6A is broadly expressed in the developing nervous system. Sema6A repels several classes of developing axons in vitro and contributes to thalamocortical axon guidance in vivo. Here we show that during cerebellum development, Sema6A is selectively expressed by postmitotic granule cells during their tangential migration in the deep external granule cell layer, but not during their radial migration. In Sema6A-deficient mice, many granule cells remain ectopic in the molecular layer where they differentiate and are contacted by mossy fibers. The analysis of ectopic granule cell morphology in Sema6a-/- mice, and of granule cell migration and neurite outgrowth in cerebellar explants, suggests that Sema6A controls the initiation of granule cell radial migration, probably through a modulation of nuclear and/or soma translocation. Finally, the analysis of mouse chimeras suggests that this function of Sema6A is primarily non-cell-autonomous.     

Inducible Cre recombinase activity in mouse cerebellar granule cell precursors and inner ear hair cells.

A transgenic mouse line expressing the CreER(TM) fusion protein under the control of the Math1 enhancer was generated. Expression of the transgene in the postnatal mouse was restricted to hair cells of the inner ear and granule neurons in the external granule layer of the cerebellum in a temporally regulated manner. Cre activity was virtually nonexistent in uninduced mice; however, treatment of newborn pups with tamoxifen, leading to nuclear translocation of the fusion protein, resulted in efficient recombination at LoxP sites in the appropriate cell types. Up to two thirds of cerebellar granule neurons and 80-90% of cochlear hair cells underwent Cre-specific recombination. This mouse line provides a powerful tool to dissect gene function at early and late stages in development of the cerebellum and inner ear.     

The effects of neurotrophin-3 and brain-derived neurotrophic factor on cerebellar granule cell movement and neurite extension in vitro

Migration of the granule cells is a major stage of cerebellar maturation. Granule cells express neurotrophins and their receptors; however, their role in cell migration has not been defined. In this study we investigated the effects of exogenous neurotrophins on the movement and neurite extension of granule cells from glial-free cerebellar cell reaggregates in vitro. Our results provide direct evidence that neurotrophin-3 and brain-derived neurotrophic factor differentially affect the granule cells. Neurotrophin-3 significantly affected granule cell movements by decreasing the migration index (the ratio of the number of cells that moved further than half the neurite length) and the speed of cell soma movement, but did not affect neurite length or growth cone migration. In contrast, brain-derived neurotrophic factor and neurotrophin-4 acted on growing neurites and growth cones by significantly increasing neurite length and the speed of growth cone migration, but had no effect either on the migration index or on the speed of the cell soma movement.The results suggest that neurotrophins differentially affect neurite extension and the movements of cerebellar granule cells.     

Palmitoylation-dependent endosomal localization of AATYK1A and its interaction with Src

Apoptosis-associated tyrosine kinase 1 (AATYK1), also named LMTK1, was previously isolated as an apoptosis-related gene from 32Dcl3 myeloid precursor cells, but its precise function remains unknown. AATYK1A, an isoform without a transmembrane domain, is highly expressed in neurons. We identified palmitoylation of AATYK1A at three N-terminal cysteine residues in cortical cultured neurons and COS-7 cells and found that palmitoylation determined localization of AATYK1A to the transferrin receptor-positive recycling endosomes. Further, we identified the tyrosine kinase Src as a novel AATYK1A-interacting protein. Src and Fyn phosphorylated AATYK1A at tyrosines 25 and 46 in a palmitoylation-dependent manner. The association of AATYK1A with Src in endosomes was also found to be palmitoylation-dependent. These results indicate that palmitoylation is a critical factor not only for the subcellular localization of AATYK1A but also for its interaction with Src.     

Architecture of Purkinje cells of the reeler mutant mouse observed by immunohistochemistry for the inositol 1,4,5-trisphosphate receptor protein P400.

P400 protein, which is identical to the inositol 1,4,5-trisphosphate receptor protein, is a glycoprotein closely associated with the membranes of Purkinje cells. Three types of monoclonal antibodies against P400 protein were employed for the immunohistochemical detection of Purkinje cells in the cerebellum and brainstem of the normal and reeler mouse. Purkinje cells in both types of mice were immunoreactive against anti-P400 antibodies, and the soma, dendrites, axon and even terminal boutons in the cerebellar and vestibular nuclei could be clearly visualized. In the cerebellum of the reeler mutant, the heterotopic Purkinje cells both within and below the granule cell layer were also immunopositive and could be clearly differentiated from the deep cerebellar nuclei, in which neurons were immunonegative. The molecular layer of the reeler cerebellum varied in thickness and certain parts were completely defective. The dendrites within the molecular layer extended from Purkinje cells whose cell bodies were located in the normal position, abnormally in the granule cell layer, or at the surface of the central mass. Outside the cortex of the cerebellum, ectopic Purkinje cells were demonstrated in 3 cerebellar nuclei, the cerebellar medulla and peduncle, and brainstem of the normal and reeler mouse.     

Reorganization of cerebellar cell suspension transplanted into the weaver mutant cerebellum and immunohistochemical detection of synaptic formation

Dissociated cells prepared from the cerebellar primordia of normal 15-day mouse embryos were grafted into the cerebellum of 1-month-old weaver mutant mice which are characterized by degeneration of cerebellar granule cells during the early postnatal period. The growth of the grafted cells was investigated at 1 month after the operation. Implanted cells were highly developed to form a large mass of tissue in the host cerebellar folia. Histological examination revealed that a trilaminar cortical structure was partially developed in certain areas of the grafted tissue. The implanted granule-like cells were labeled with [3H]thymidine which was injected into the host, suggesting that the granule-like cells actively proliferate in the host cerebellum after the transplantation. In this area, strong immunoreactivity with synapsin I was detected indicating that the dissociated granule cells of the cerebellar primordia are able to develop a synaptic organization in the weaver mouse cerebellum.     

Histochemical characterization of lectin binding in mouse cerebellum

Eight fluorescein-isothiocyanate-conjugated lectins differing from each other in carbohydrate binding specificities have been used to reveal qualitative differences in carbohydrate composition among the various cell types of the early postnatal and adult cerebellar cortex, cerebellar deep nuclei and medulla. By treating unfixed frozen tissue sections with unconjugated lectin in the presence of excess hapten sugar and subsequently staining with fluorescein-isothiocyanate-conjugated lectin in the presence of bovine serum albumin, carbohydrate specific staining was observed for all of the lectins studied. Lectin binding was selectively inhibited by appropriate hapten sugars. For several lectins (wheat germ agglutinin, Ricinus communis agglutinins and Lens culinaris agglutinins) complex carbohydrates were required for inhibition of staining.In the adult cerebellum, concanavalin A intensely stained the soma of granule cells, synaptic glomeruli and the cytoplasm of Purkinje cells, while the molecular layer and white matter were relatively unstained. Wheat germ agglutinin heavily labeled the soma of granule cells, synaptic glomeruli, parallel fibers of the molecular layer, and the nuclear membrane of Purkinje cells, and weakly labeled the white matter. Ricinus communis agglutins (m.w. 60,000 and 120,000) intensely stained the soma of granule cells, synaptic glomeruli, parallel fibers in the molecular layer, the cytoplasm of Purkinje cells, and the white matter. None of the above lectins stained Purkinje cell dendrites. Lens culinaris lectins A and B stained the soma of granule cells, synaptic glomeruli, the cytoplasm of Purkinje cells, Purkinje cell dendrites, and white matter.In the 5- and 12-day-old postnatal cerebellum, concanavalin A stained the molecular layer more strongly than in the adult. Concanavalin A, wheat germ agglutinin and Lens culinaris lectins moderately stained cell cytoplasm in the external and internal granule layers, but the external granule cell layer was heavily labeled with both Ricinus communis lectins. With the soybean agglutinin, weak staining of the molecular layer and synaptic glomeruli was detected in young cerebellum, in contrast to adult tissue where no staining was observed. No labeling of the young or adult cerebellum was observed with Ulex europaeus agglutinin I.The specific patterns of staining with different lectins probably reflect the different carbohydrate compositions of the various cell types and perhaps of the intercellular matrix.     

Involvement of BREK, a serine/threonine kinase enriched in brain, in NGF signalling

We identified AATYK2 (Apoptosis-Associated Tyrosine Kinase 2) through a database search as a kinase specifically expressed in the brain. After characterization, we renamed it BREK (Brain-Enriched Kinase). Mouse BREK mRNA is expressed predominantly in brain, especially in olfactory bulb, olfactory tubercle, hippocampus, striatum, cerebellum, and cerebral cortex. Levels of expression and phosphorylation of BREK were high at 0-2 weeks after birth, suggesting that BREK is involved in neural development and functions during the early postnatal period. Phosphoamino acid analysis following in vitro kinase reaction revealed that BREK is a catalytically active, serine/threonine kinase. In PC12 cells, BREK was phosphorylated rapidly upon stimulation with nerve growth factor (NGF) in a protein kinase C-dependent pathway. In differentiated PC12 cells, BREK was enriched in cell bodies and growth cones, and also present along neurites. Introduction of a kinase-defective mutant of BREK into PC12 cells enhanced both ERK phosphorylation and neurite outgrowth in response to NGF, suggesting that BREK is a negative regulator of NGF-induced neuronal differentiation. Thus, we conclude that BREK is a new member of the family of protein serine/threonine kinases and that it plays important roles in NGF-TrkA signalling.     

AATYK1A phosphorylation by Cdk5 regulates the recycling endosome pathway

Trafficking of recycling endosomes (REs) is regulated by the small GTPase, Rab11A; however, the regulatory mechanism remains elusive. Apoptosis‐associated tyrosine kinase 1A (AATYK1A) is a Ser/Thr kinase expressed highly in brain. We have recently shown that AATYK1A localizes to Rab11A‐positive RE and is phosphorylated at Ser34 by cyclin‐dependent kinase 5 (Cdk5). Here, we have investigated a role of AATYK1A and its phosphorylation in recycling endosomal trafficking using Chinese hamster ovary‐K1 (CHO‐K1) cells. AATYK1A localizes predominantly to Rab11A‐positive pericentrosomal endocytic recycling compartment (ERC). Phosphorylation at Ser34 of AATYK1A disrupts its accumulation in the pericentrosomal ERC. Consistently, phosphorylation‐mimic mutant (AATYK1A‐S34D) did not accumulate in the ERC and additionally attenuated ERC formation. ERC formation suppression can be reversed by constitutively active Rab11A‐Q70L, suggesting a functional link between AATYK1A phosphorylation and Rab11A activity. Although no direct interaction between AATYK1A and Rab11A could be detected, the exchange of guanine nucleotides bound to Rab11A was significantly reduced in the presence of the phosphorylation‐mimic AATYK1A‐S34D. Together, our results reveal a regulatory role for AATYK1A in the formation of pericentrosomal ERC. They furthermore indicate that Cdk5 can disrupt ERC formation via Ser34 phosphorylation of AATYK1A. Finally, our data suggest a mechanism by which AATYK1A signaling couples Cdk5 to Rab11A activity.     

Ca/calmodulin-dependent protein kinase II in the rat cerebellum: An immunohistochemical study with monoclonal antibodies specific to either α or β subunit

Monoclonal antibodies specific to either α or β subunit of Ca²⁺/calmodulin-dependent protein kinase II (CaM kinase II) of the rat brain were produced and the distribution of each subunit in the rat cerebellum was examined immunohistochemically. Each antibody detected solely the corresponding subunit in immunoblot analysis of crude homogenates of the rat forebrain and cerebellum, and purified CaM kinase II from the rat forebrain. Immunoreactivity for α subunit was present selectively in Purkinje cells: perikarya, dendrites with their spines, axons and their terminal-like structures in the cerebellar cortex, cerebellar nuclei and lateral vestibular nucleus. Many of these α subunit-immunoreactive axons from the cerebellum were traced only through the inferior cerebellar peduncle. β Subunit was detected in perikarya and dendrites of a limited number of Purkinje cells, many granule cells and neurons in the cerebellar nuclei. Thus, different distributions of α and β subunits of CaM kinase II in the cerebellum were demonstrated.     

Expression of neurofilament immunoreactivity in developing rat cerebellum in vitro and in vivo

The developmental expression of neurofilaments immunoreactivity was examined in frozen sections and in primary cultures of rat cerebellum by immunocytochemistry with a series of monoclonal antibodies and with a polyclonal antibody. In tissue sections immunocytochemical staining with all the antibodies used was observed in basket cells where adult-like appearance could be detected by 14 days of age and adult-level intensity was achieved by about 25 days. Granule cells remained unstained. Intense staining appeared in cerebellar white matter as early as 7 days after birth. In contrast, neurofilaments immunoreactivity was detected in cultured granule cells from 7-day-old cerebellum. Only polyclonal antibodies reacting with the highly conserved middle alpha-helical domain of the neurofilament subunits were reactive in culture. Staining could be detected in the nerve cell bodies from the first day after plating; thereafter staining intensity increased and was also distributed in neurite extensions. We conclude that unlike their counterparts in vivo cultured embryonic granule cells can express certain neurofilaments immunoreactivity.     

New insights into the molecular basis of progressive myoclonus epilepsy: a multiprotein complex with cystatin B

Cystatin B is an anti-proteolytic polypeptide implicated in progressive myoclonus epilepsy (EPM1), a degenerative disease of the central nervous system. The knock-out mouse model of the disease shows apoptosis of the cerebellar granule cells. We have identified five recombinant proteins interacting with cystatin B and none of them is a protease. We show that three of these proteins (RACK-1, beta-spectrin and NF-L) co-immunoprecipitate with cystatin B in rat cerebellum. Confocal immunofluorescence analysis shows that the same proteins are present in the granule cells of developing cerebellum, as well as in Purkinje cells of adult rat cerebellum. We propose that a cystatin B multiprotein complex has a specific cerebellar function and that the loss of this function might contribute to the disease in EPM1 patients.     

AMPA receptors are modulated by tachykinins in rat cerebellum neurons

The peptides of the tachykinin family are widely distributed within the mammalian peripheral and central nervous systems and play a well-recognized role as neuromodulators, although their direct action on cerebellum granule cells have not yet been demonstrated. We have examined the effect of the best known members of the family, substance P (SP), neurokinin A (NKA), and neurokinin B (NKB) on alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptors from rat cerebellar granule cells in culture to assess the ability of these peptides to regulate the glutamatergic input. Both NKA and NKB, but not SP, produce a significant enhancement of ionic current through AMPA receptors activated by the agonist kainate in 53.5 and 46% of patched neurons, respectively. This effect was not observable in the presence of MEN 10,627 and Trp(7)betaAla(8), NKA and NKB competitive antagonist receptors, respectively, indicating that the current modulations were mediated by the respective receptors. NKB also produces a significant enhancement of ionic current through the AMPA receptors activated directly by its agonist AMPA and cyclothiazide, an allosteric modulator that selectively suppresses desensitization of AMPA receptors. The presence of NK3 receptors was demonstrated in these neurons by RT-PCR amplification of total RNA extracted from cerebellar granule cells, using NK3-specific primer pairs. Immunocytochemistry experiments, using a specific polyclonal antibody directed against NK3, also confirmed the presence of NK3 receptors and their co-localization with the GLUR2 AMPA subunit in about 54% of cerebellar granule neurons. This study adds the tachykinins to the list of neuromodulators capable of exerting a excitatory action on cerebellar granule cells.     

Ca2+/calmodulin-dependent protein kinase II in the rat cerebellum: an immunohistochemical study with monoclonal antibodies specific to either alpha or beta subunit.

Monoclonal antibodies specific to either alpha or beta subunit of Ca2+/calmodulin-dependent protein kinase II (CaM kinase II) of the rat brain were produced and the distribution of each subunit in the rat cerebellum was examined immunohistochemically. Each antibody detected solely the corresponding subunit in immunoblot analysis of crude homogenates of the rat forebrain and cerebellum, and purified CaM kinase II from the rat forebrain. Immunoreactivity for alpha subunit was present selectively in Purkinje cells: perikarya, dendrites with their spines, axons and their terminal-like structures in the cerebellar cortex, cerebellar nuclei and lateral vestibular nucleus. Many of these alpha subunit-immunoreactive axons from the cerebellum were traced only through the inferior cerebellar peduncle. beta Subunit was detected in perikarya and dendrites of a limited number of Purkinje cells, many granule cells and neurons in the cerebellar nuclei. Thus, different distributions of alpha and beta subunits of CaM kinase II in the cerebellum were demonstrated.     

On the location of gamma-aminobutyrate and benzodiazepine receptors in the cerebellum of the normal C3H and Lurcher mutant mouse

Binding of gamma-aminobutyrate and benzodiazepine receptor ligands has been studied in the cerebellum of adult normal (C3H) and Lurcher mutant mice. The adult mutant has lost all Purkinje cells and more than 90% of the granule cells in the cerebellar cortex. When compared with their normal littermates Lurcher mice displayed large decreases in the number of high-affinity binding sites for [3H]muscimol, a synaptic gamma-aminobutyrate receptor ligand, in washed cerebellar homogenates. This observation was consistent with the extensive loss of gamma-aminobutyrate receptive Purkinje and granule cells from the Lurcher cerebellum. However, specific binding of the benzodiazepine-receptor ligand [3H]flunitrazepam to Lurcher cerebellum remained unchanged. Indeed quantitative autoradiography, employing [3H]flunitrazepam as a photoaffinity label, showed no significant differences in the density of labelling between Lurcher and normal littermate mice in any region of the cerebellum. These benzodiazepine binding sites in washed homogenates or tissue sections displayed a gamma-aminobutyrate-induced enhancement of [3H]flunitrazepam binding which occurred to the same extent in both Lurcher and normal cerebellum, a facilitatory effect which could be blocked by the addition of bicuculline methobromide. Our results suggest that a large proportion of the high-affinity, specific benzodiazepine binding sites in mouse cerebellum are not coupled to the synaptic gamma-aminobutyrate receptors thought to be labelled by high affinity [3H]muscimol binding. Further, that benzodiazepine binding sites do not appear to be enriched on either the soma or dendrites of Purkinje cells, as has been suggested from previous studies. Investigations at the electron microscope level are now required to elucidate the cellular location of benzodiazepine binding sites in the cerebellar cortex and to examine whether or not they are likely to be exposed to gamma-aminobutyrate in vivo.     

Neurotrophic effects of leptin on cerebellar Purkinje but not granule neurons in vitro

As recent evidence has revealed a pro-survival role for the anti-obesity hormone leptin in the nervous system, we investigated the generality of this finding on cerebellar Purkinje and granule neurons in vitro. We found that whilst leptin promoted cerebellar Purkinje neuron survival, it had no affect on cerebellar granule cells. In addition, we discovered that leptin promoted both the outgrowth of neurites from cerebellar Purkinje neurons and increased the complexity of the neurite arbor. Thus, leptin has different effects on two neighbouring populations of neurons within the cerebellum implying specificity of its actions in the central nervous system.     

Abnormalities in premigratory granule cells in the weaver cerebellum defined by monoclonal antibody OZ42

Summary The immunoreactivity in OZ42, a neural cell specific antibody that recognizes premigratory cerebellar granule cells, was examined in early postnatal wild-type and weaver mouse cerebella. We find that the OZ42-positive staining in the external granular layer (EGL) is first seen at postnatal day 1 in the most posterior and ventral aspect of midline cerebellum in the wild-type and heterozygous weaver mouse. By postnatal day 4 strong immunoreactivity is observed in the EGL of all cerebellar lobules. This staining is localized to a band of immunoreactive cells present at the interface of the EGL and the molecular layer (ML). In the homozygous weaver cerebellum, OZ42-positive staining is not seen until post-natal day 3. In the postnatal day 4 weaver cerebellum, immunoreactivity is considerably ligther than in littermate control cerebella, and found throughout the width of the EGL (i.e., not localized to the EGL-ML interface).This study demonstrates that the expression of a specific marker of granule cell development is abnormal in the granule cell population of the homozygous weaver mouse, a population of cells known to be intrinsically affected by the action of this mutant gene. In the light of previous studies, which have shown that the weaver phenotype is identifiable as early as the day of birth, and that the OZ42-antigen may be involved with the development process of axonal growth, it is reasonable to suggest that the weaver mutation results in an abnormality in the ability of granule cells to produce and/or stabilize axons.     

Regional differences in cytoarchitecture of the weaver cerebellum suggest a new model for weaver gene action

This paper examines the structure and cytoarchitecture of the cerebellum of the weaver mutant mouse with particular emphasis on regional differences along the mediolateral and anterior-posterior axes. We have uncovered several, previously undescribed features of the weaver cerebellar phenotype. Perhaps the most dramatic example of our findings is the severe disruption of the folial structure of the hemispheres of the weaver cerebellum. A dorsal overgrowth of tissue occurs in the hemispheres that forms a finger-like projection superficial to an atrophic but structurally more normal cerebellar mass underneath. While this folial abnormality is most evident in the homozygote (wv/wv) the antecedents of its appearance are already apparent in the heterozygote (+/wv). At the level of the cytoarchitectonics of the mutant brain, we find substantial variation in the positioning, numbers and density of both Purkinje and granule cells. As a whole, Purkinje plus Golgi II cell numbers are down by over 40%, but this reduction occurs almost exclusively in the medial half of the cerebellum. The hemispheric region contains a nearly normal number of cells per sagittal section (although their positions are predominantly incorrect). The granule cells also show numerical variation; they are nearly absent at the midline, but a substantial number of them survive in the lateral cerebellar cortex. In the paraflocculus, for example, granule cells can be observed in a modest internal granule cell layer as late as 38 postnatal days. These results are discussed in terms of a model of wv gene action in which we propose that the effect of the mutation is a general disruption of cellular distribution in the cerebellar cortex, affecting both Purkinje and granule cells and beginning prenatally.