Calcium-induced calcium release from intracellular stores is developmentally regulated in primary cultures of cerebellar granule neurons

The properties of depolarization-evoked calcium transients are known to change during the maturation of dissociated cerebellar granule neuron cultures. Here, we assessed the role of the calcium-induced calcium release (CICR) mechanism in granule neuron maturation. Both depletion of intracellular calcium stores and the pharmacological blockade of CICR significantly reduced depolarization stimulated calcium transients in young but not older (>/=1 week) cultures. This functional decrease in the CICR signaling component was associated with the reduction of ryanodine receptor (RyR) immunoreactivity during granule neuron maturation both in culture and in the intact cerebellum. These observations are consistent with the idea that changes in RyR expression result in functional changes in calcium signaling transients during normal neuronal development in the intact mammalian cerebellum as well as in reduced neuronal cultures. Pharmacological disruption of CICR during neuron differentiation in vitro resulted in dose-dependent changes in survival, GAP-43 expression, and the acquisition of the glutamatergic neurotransmitter phenotype. Together, these results indicate that CICR function plays a physiologically relevant role in regulating early granule neuron differentiation in vitro and is likely to play a role in cerebellar maturation.     

α-internexin is the only neuronal intermediate filament expressed in developing cerebellar granule neurons

We have used immunocytochemistry and in situ hybridization to examine the distribution of neuronal intermediate filament proteins and their mRNAs in the developing mouse cerebellum. First, we demonstrate that α-internexin is abundantly expressed in the developing cerebellum and is the only neuronal intermediate filament protein expressed in developing, including migrating, granule neurons. Second, in granule neuron reaggregates in vitro, α-internexin is the only neuronal intermediate filament protein highly expressed in the processes of the cultured granule neurons. This in vitro observation is consistent with results from immunocytochemistry and in situ hybridization studies of developing granule neurons in vivo, which suggest that α-internexin is the major neuronal intermediate filament protein in developing granule neurons. Finally, the neurofilament triplet proteins are expressed later, and coexist with α-internexin in other cells, including Purkinje cells and interneurons in the mature mouse cerebellum. These changes in neuronal intermediate filament composition may regulate neuronal maturation and axonal stability in cerebellar development. Furthermore, α-internexin may play a key role in neurite outgrowth and the establishment of neuronal cytoarchitecture. © 1996 John Wiley & Sons, Inc.     

Dendritic differentiation of cerebellar Purkinje cells is promoted by ryanodine receptors expressed by Purkinje and granule cells

Cerebellar Purkinje cells have the most elaborate dendritic trees among neurons in the brain. We examined the roles of ryanodine receptor (RyR), an intracellular Ca²⁺ release channel, in the dendrite formation of Purkinje cells using cerebellar cell cultures. In the cerebellum, Purkinje cells express RyR1 and RyR2, whereas granule cells express RyR2. When ryanodine (10 µM), a blocker of RyR, was added to the culture medium, the elongation and branching of Purkinje cell dendrites were markedly inhibited. When we transferred small interfering RNA (siRNA) against RyR1 into Purkinje cells using single‐cell electroporation, dendritic branching but not elongation of the electroporated Purkinje cells was inhibited. On the other hand, transfection of RyR2 siRNA into granule cells also inhibited dendritic branching of Purkinje cells. Furthermore, ryanodine reduced the levels of brain‐derived neurotrophic factor (BDNF) in the culture medium. The ryanodine‐induced inhibition of dendritic differentiation was partially rescued when BDNF was exogenously added to the culture medium in addition to ryanodine. Overall, these results suggest that RyRs expressed by both Purkinje and granule cells play important roles in promoting the dendritic differentiation of Purkinje cells and that RyR2 expressed by granule cells is involved in the secretion of BDNF from granule cells. © 2013 Wiley Periodicals, Inc. Develop Neurobiol 74: 467–480, 2014     

Effects of voltage‐gated calcium channel subunit genes on calcium influx in cultured C. elegans mechanosensory neurons

Voltage‐gated calcium channels (VGCCs) serve as a critical link between electrical signaling and diverse cellular processes in neurons. We have exploited recent advances in genetically encoded calcium sensors and in culture techniques to investigate how the VGCC α₁ subunit EGL‐19 and α₂/δ subunit UNC‐36 affect the functional properties of C. elegans mechanosensory neurons. Using the protein‐based optical indicator cameleon, we recorded calcium transients from cultured mechanosensory neurons in response to transient depolarization. We observed that in these cultured cells, calcium transients induced by extracellular potassium were significantly reduced by a reduction‐of‐function mutation in egl‐19 and significantly reduced by L‐type calcium channel inhibitors; thus, a main source of touch neuron calcium transients appeared to be influx of extracellular calcium through L‐type channels. Transients did not depend directly on intracellular calcium stores, although a store‐independent 2‐APB and gadolinium‐sensitive calcium flux was detected. The transients were also significantly reduced by mutations in unc‐36, which encodes the main neuronal α₂/δ subunit in C. elegans. Interestingly, while egl‐19 mutations resulted in similar reductions in calcium influx at all stimulus strengths, unc‐36 mutations preferentially affected responses to smaller depolarizations. These experiments suggest a central role for EGL‐19 and UNC‐36 in excitability and functional activity of the mechanosensory neurons. © 2006 Wiley Periodicals, Inc. J Neurobiol, 2006     

GPI‐anchored human placental alkaline phosphatase has a nonpolarized distribution on the cell surface of mouse cerebellar granule neurons in vitro

The glycosyl phosphatidylinositol (GPI) lipid anchor, which directs GPI‐anchored proteins to the apical cell surface in certain polarized epithelial cell types, has been proposed to act as an axonal protein targeting signal in neurons. However, as several GPI‐anchored proteins have been found on both the axonal and somatodendritic cell‐surface domains of a variety of neuronal cell types, the role of the GPI anchor in protein localization to the axon remains unclear. To begin to address the role of the GPI anchor in neuronal protein localization, we used a replication‐incompetent retroviral vector to express a model GPI‐anchored protein, human placental alkaline phosphatase (hPLAP), in early postnatal mouse cerebellar granule neurons developing in vitro. Purified granule neurons were cultured in large mitotically active cellular reaggregates to allow retroviral infection of undifferentiated, proliferating granule neuron precursors. To more easily visualize hPLAP localization during the sequence of differentiation of single postmitotic granule neurons, reaggregates were dissociated following infection, plated as high‐density monolayers, and maintained for 1–9 days under serum‐free culture conditions. As we previously demonstrated for uninfected granule neurons developing in monolayer culture, hPLAP‐expressing granule neurons likewise developed in vitro through a series of discrete temporal stages highly similar to those observed in situ. hPLAP‐expressing granule neurons first extended either a single neurite or two axonal processes, and subsequently attained a mature, well‐polarized morphology consisting of multiple short dendrites and one or two axons that extended up to 3 mm across the culture substratum. hPLAP was expressed uniformly on the entire cell surface at each stage of granule neuron differentiation. Thus, it appears that the GPI anchor is not sufficient to confer axonal localization to an exogenous GPI‐anchored protein expressed in a well‐polarized primary neuronal cell type in vitro; other signals, such asthose present in the extracellular domain of these proteins, may be necessary for the polarized targeting or retention of axon‐specific GPI‐anchored proteins. © 1999 John Wiley & Sons, Inc. J Neurobiol 39: 119–141, 1999     

Nmyc upregulation by sonic hedgehog signaling promotes proliferation in developing cerebellar granule neuron precursors

Hedgehog pathway activation is required for expansion of specific neuronal precursor populations during development and is etiologic in the human cerebellar tumor, medulloblastoma. We report that sonic hedgehog (Shh) signaling upregulates expression of the proto-oncogene Nmyc in cultured cerebellar granule neuron precursors (CGNPs) in the absence of new protein synthesis. The temporal-spatial expression pattern of Nmyc, but not other Myc family members, precisely coincides with regions of hedgehog proliferative activity in the developing cerebellum and is observed in medulloblastomas of Patched (Ptch) heterozygous mice. Overexpression of Nmyc promotes cell-autonomous G(1) cyclin upregulation and CGNP proliferation independent of Shh signaling. Furthermore, Myc antagonism in vitro significantly decreases proliferative effects of Shh in cultured CGNPs. Together, these findings identify Nmyc as a direct target of the Shh pathway that functions to regulate cell cycle progression in cerebellar granule neuron precursors.     

Primary Cilia in the Murine Cerebellum and in Mutant Models of Medulloblastoma

Cellular primary cilia crucially sense and transduce extracellular physicochemical stimuli. Cilium-mediated developmental signaling is tissue and cell type specific. Primary cilia are required for cerebellar differentiation and sonic hedgehog (Shh)-dependent proliferation of neuronal granule precursors. The mammalian G-protein-coupled receptor 37-like 1 is specifically expressed in cerebellar Bergmann glia astrocytes and participates in regulating postnatal cerebellar granule neuron proliferation/differentiation and Bergmann glia and Purkinje neuron maturation. The mouse receptor protein interacts with the patched 1 component of the cilium-associated Shh receptor complex. Mice heterozygous for patched homolog 1 mutations, like heterozygous patched 1 humans, have a higher incidence of Shh subgroup medulloblastoma (MB) and other tumors. Cerebellar cells bearing primary cilia were identified during postnatal development and in adulthood in two mouse strains with altered Shh signaling: a G-protein-coupled receptor 37-like 1 null mutant and an MB-susceptible, heterozygous patched homolog 1 mutant. In addition to granule and Purkinje neurons, primary cilia were also expressed by Bergmann glia astrocytes in both wild-type and mutant animals, from birth to adulthood. Variations in ciliary number and length were related to the different levels of neuronal and glial cell proliferation and maturation, during postnatal cerebellar development. Primary cilia were also detected in pre-neoplastic MB lesions in heterozygous patched homolog 1 mutant mice and they could represent specific markers for the development and analysis of novel cerebellar oncogenic models.     

Shp2 acts downstream of SDF-1α/CXCR4 in guiding granule cell migration during cerebellar development

Shp2 is a non-receptor protein tyrosine phosphatase containing two Src homology 2 (SH2) domains that is implicated in intracellular signaling events controlling cell proliferation, differentiation and migration. To examine the role of Shp2 in brain development, we created mice with Shp2 selectively deleted in neural stem/progenitor cells. Homozygous mutant mice exhibited early postnatal lethality with defects in neural stem cell self-renewal and neuronal/glial cell fate specification. Here we report a critical role of Shp2 in guiding neuronal cell migration in the cerebellum. In homozygous mutants, we observed reduced and less foliated cerebellum, ectopic presence of external granule cells and mispositioned Purkinje cells, a phenotype very similar to that of mutant mice lacking either SDF-1α or CXCR4. Consistently, Shp2-deficient granule cells failed to migrate toward SDF-1α in an in vitro cell migration assay, and SDF-1α treatment triggered a robust induction of tyrosyl phosphorylation on Shp2. Together, these results suggest that although Shp2 is involved in multiple signaling events during brain development, a prominent role of the phosphatase is to mediate SDF-1α/CXCR4 signal in guiding cerebellar granule cell migration.     

Excitotoxin-induced changes in transglutaminase during differentiation of cerebellar granule cells

Summary. Excitotoxicity induced by NMDA receptor stimulation is able to increase the activity of many enzymes involved in neuronal cell death. Primary cultures of rat cerebellar granule cells were used to elucidate the role of transglutaminase reaction in the excitotoxic cell response, and to evaluate the role of glutamate receptors in cell survival and degeneration. Granule neurons, maintained in vitro for two weeks, were exposed to NMDA at different stages of differentiation. Following NMDA receptor activation, increases in transglutaminase activity were observed in cell cultures. The levels of enzyme activity were higher in cells at 5 days in vitro than in those at 8–9 or 13–14 days in vitro. Moreover, NMDA exposure up-regulated tTG expression in neurons as young as 5 days in vitro. These cultures also exhibited morphological changes with clear apoptotic features. Results obtained demonstrate that susceptibility of granule cells to excitotoxicity depends on the developmental stage of neurons.     

Regulation of Neuronal Morphogenesis and Positioning by Ubiquitin-Specific Proteases in the Cerebellum

Ubiquitin signaling mechanisms play fundamental roles in the cell-intrinsic control of neuronal morphogenesis and connectivity in the brain. However, whereas specific ubiquitin ligases have been implicated in key steps of neural circuit assembly, the roles of ubiquitin-specific proteases (USPs) in the establishment of neuronal connectivity have remained unexplored. Here, we report a comprehensive analysis of USP family members in granule neuron morphogenesis and positioning in the rodent cerebellum. We identify a set of 32 USPs that are expressed in granule neurons. We also characterize the subcellular localization of the 32 USPs in granule neurons using a library of expression plasmids encoding GFP-USPs. In RNAi screens of the 32 neuronally expressed USPs, we uncover novel functions for USP1, USP4, and USP20 in the morphogenesis of granule neuron dendrites and axons and we identify a requirement for USP30 and USP33 in granule neuron migration in the rodent cerebellar cortex in vivo. These studies reveal that specific USPs with distinct spatial localizations harbor key functions in the control of neuronal morphogenesis and positioning in the mammalian cerebellum, with important implications for our understanding of the cell-intrinsic mechanisms that govern neural circuit assembly in the brain.     

Decreased calretinin expression in cerebellar granule cells in the leaner mouse

We investigated calretinin expression in cerebellar granule cells of 30-day-old leaner mice to understand possible changes in calcium homeostasis due to the calcium channel mutation that these mice carry. Quantitative in situ hybridization histochemistry showed decreased calretinin mRNA expression in the leaner cerebellum. Immunohistochemical staining also revealed decreased calretinin immunoreactivity in the leaner cerebellum. To exclude the effect of granule cell loss that occurs in the leaner mouse when comparing cerebellar calretinin expression, the number of granule cells per unit area in the cerebellum was compared to the wild-type cerebellum. Granule cell counts per unit area of cerebellum revealed similar numbers of granule cells present in wild-type and leaner mice. Laser capture microdissection (LCM) was employed to obtain an equal number of granule cells from wild-type and leaner mice. Western blot analysis with LCM-procured cerebellar granule cells showed decreased calretinin expression in leaner granule cells. These results indicate that there is an absolute decrease in calretinin expression in leaner granule cells even when granule cell loss is taken into account. Decreased calretinin expression in leaner granule cells may contribute to altered calcium buffering capacity. This alteration could be an adaptive change due to the calcium channel dysfunction, and may result in abnormal neuronal excitability and gene expression.     

Localization of tissue plasminogen activator mRNA in the developing rat cerebellum and effects of inhibiting tissue plasminogen activator on granule cell migration

Tissue plasminogen activator (tPA) mRNA was localized in the developing cerebellum and the potentials role of tPA in migration of cerebellar granule cells was investigated. Proteolytic assays and Northern blots showed little variation in levels of tPA proteolytic activity or tPA mRNA expression in the developing cerebellum. The distribution of cerebellar tPA mRNA at different ages was visualized by in situ hybridization histochemistry. At postnatal day 7 (P7), most labeled cells were in the internal granule layer or developing white matter, and very few if any premigratory granule cells contained tPA mRNA. Although the molecular layer contained labeled cells at all ages, cell counts indicated that a greater percentage of cells in the molecular layer contained tPA mRNA during adulthood than during the period of granule cell migration. The most striking change in tPA mRNA expression was in Purkinje neurons, most of which began to express tPA mRNA between P7 and P14. The potential role of tPA in granule cell migration was investigated by performing migration assays in cerebellar slice explants in the presence or absence of protease inhibitors. The presence of inhibitors did not affect the distance that granule cells migrated. Data in the present study do not support a role for tPA in granule neuron migration; however, they do indicate that tPA is both spatially and temporally regulated during cerebellar development. Possible functions of tPA in the cerebellum are discussed. © 1995 John Wiley & Sons, Inc.     

Calcium signaling in the developing Xenopus myotome.

Embryonic Xenopus myocytes generate spontaneous calcium (Ca(2+)) transients during differentiation in culture. Suppression of these transients disrupts myofibril organization and the formation of sarcomeres through an identified signal transduction cascade. Since transients often occur during myocyte polarization and migration in culture, we hypothesized they might play additional roles in vivo during tissue formation. We have tested this hypothesis by examining Ca(2+) dynamics in the intact Xenopus paraxial mesoderm as it differentiates into the mature myotome. We find that Ca(2+) transients occur in cells of the developing myotome with characteristics remarkably similar to those in cultured myocytes. Transients produced within the myotome are correlated with somitogenesis as well as myocyte maturation. Since transients arise from intracellular stores in cultured myocytes, we examined the functional distribution of both IP(3) and ryanodine receptors in the intact myotome by eliciting Ca(2+) elevations in response to photorelease of caged IP(3) and superfusion of caffeine, respectively. As in culture, transients in vivo depend on Ca(2+) release from ryanodine receptor (RyR) stores, and blocking RyR during development interferes with somite maturation.     

The calcium‐sensing receptor and integrins modulate cerebellar granule cell precursor differentiation and migration

In the developing cerebellum granule cell precursors (GCPs) proliferate in the external granule cell layer before differentiating and migrating to the inner granule cell layer. Aberrant GCP proliferation leads to medulloblastoma, the most prevalent form of childhood brain cancer. Here, we demonstrate that the calcium‐sensing receptor (CaSR), a homodimeric G‐protein coupled receptor, functions in conjunction with cell adhesion proteins, the integrins, to enhance GCP migration and cell homing by promoting GCP differentiation. During the second postnatal week a robust peak in CaSR expression was observed in GCPs; reciprocal immunoprecipitation experiments conducted during this period established that the CaSR and β1 integrins are present together in a macromolecular protein complex. Analysis of cell‐surface proteins demonstrated that activation of the CaSR by positive allosteric modulators promoted plasma membrane expression of β1 integrins via ERK2 and AKT phosphorylation and resulted in increased GCP migration toward an extracellular matrix protein. The results of in vivo experiments whereby CaSR modulators were injected i.c.v. revealed that CaSR activation promoted radial migration of GCPs by enhancing GCP differentiation, and conversely, a CaSR inhibitor disrupted GCP differentiation and promoted GCP proliferation. Our results demonstrate that an ion‐sensing G‐protein coupled receptor acts to promote neuronal differentiation and homing during cerebellar maturation. These findings together with those of others also suggest that CaSR/integrin complexes act to transduce extracellular calcium signals into cellular movement, and may function in this capacity as a universal cell migration/homing complex in the developing brain. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 76: 375–389, 2016     

Synthetic bastadins modify the activity of ryanodine receptors in cultured cerebellar granule cells

Although the interactions of several natural bastadins with the RyR1 isoform of the ryanodine receptor in sarcoplasmic reticulum has been described, their structure-dependent interference with the RyR2 isoform, mainly expressed in cardiac muscle and brain neurons, has not been studied. In this work, we examined calcium transients induced by natural bastadin 10 and several synthetic bastadins in cultured cerebellar granule cells known to contain RyR2. The fluorescent calcium indicator fluo-3 and confocal microscopy were used to evaluate changes in the intracellular Ca(2+) concentration (Ca(i)), and the involvement of ryanodine receptors was assessed using pharmacological tools. Our results demonstrate that apart from the inactive BAST218F6 (a bisdebromo analogue of bastadin 10), synthetic bastadin 5, and synthetic analogues BAST217B, BAST240 and BAST268 (at concentrations >20 microM) increased Ca(i) in a concentration-dependent, ryanodine- and FK-506-sensitive way, with a potency significantly exceeding that of 20 mM caffeine. Moreover, the same active bastadins at a concentration of 5 muM in the presence of ryanodine prevented a thapsigargin-induced increase in Ca(i). These results indicate that bastadins, acting in a structure-dependent manner, modify the activity of RyR2 in primary neuronal culture and provide new information about structure-related pharmacological properties of bastadins.     

The immunoglobulin‐like superfamily member IGSF3 is a developmentally regulated protein that controls neuronal morphogenesis

The establishment of a functional brain depends on the fine regulation and coordination of many processes, including neurogenesis, differentiation, dendritogenesis, axonogenesis, and synaptogenesis. Proteins of the immunoglobulin‐like superfamily (IGSF) are major regulators during this sequence of events. Different members of this class of proteins play nonoverlapping functions at specific developmental time‐points, as shown in particular by studies of the cerebellum. We have identified a member of the little studied EWI subfamily of IGSF, the protein IGSF3, as a membrane protein expressed in a neuron specific‐ and time‐dependent manner during brain development. In the cerebellum, it is transiently found in membranes of differentiating granule cells, and is particularly concentrated at axon terminals. There it co‐localizes with other IGSF proteins with well‐known functions in cerebellar development: TAG‐1 and L1. Functional analysis shows that IGSF3 controls the differentiation of granule cells, more precisely axonal growth and branching. Biochemical experiments demonstrate that, in the developing brain, IGSF3 is in a complex with the tetraspanin TSPAN7, a membrane protein mutated in several forms of X‐linked intellectual disabilities. In cerebellar granule cells, TSPAN7 promotes axonal branching and the size of TSPAN7 clusters is increased by downregulation of IGSF3. Thus IGSF3 is a novel regulator of neuronal morphogenesis that might function through interactions with multiple partners including the tetraspanin TSPAN7. This developmentally regulated protein might thus be at the center of a new signaling pathway controlling brain development. © 2016 Wiley Periodicals, Inc. Develop Neurobiol 77: 75–92, 2017     

Ex Vivo Culture of Chick Cerebellar Slices and Spatially Targeted Electroporation of Granule Cell Precursors

The cerebellar external granule layer (EGL) is the site of the largest transit amplification in the developing brain, and an excellent model for studying neuronal proliferation and differentiation. In addition, evolutionary modifications of its proliferative capability have been responsible for the dramatic expansion of cerebellar size in the amniotes, making the cerebellum an excellent model for evo-devo studies of the vertebrate brain. The constituent cells of the EGL, cerebellar granule progenitors, also represent a significant cell of origin for medulloblastoma, the most prevalent paediatric neuronal tumour. Following transit amplification, granule precursors migrate radially into the internal granular layer of the cerebellum where they represent the largest neuronal population in the mature mammalian brain. In chick, the peak of EGL proliferation occurs towards the end of the second week of gestation. In order to target genetic modification to this layer at the peak of proliferation, we have developed a method for genetic manipulation through ex vivo electroporation of cerebellum slices from embryonic Day 14 chick embryos. This method recapitulates several important aspects of in vivo granule neuron development and will be useful in generating a thorough understanding of cerebellar granule cell proliferation and differentiation, and thus of cerebellum development, evolution and disease.