Tomoo Hirano

Impairment of motor coordination, Purkinje cell synapse formation, and cerebellar long-term depression in GluRδ2 mutant mice

Of the six glutamate receptor (GluR) channel subunit families identified by molecular cloning, five have been shown to constitute either the AMPA, kainate, or NMDA receptor channel, whereas the function of the delta subunit family remains unknown. The selective localization of the delta 2 subunit of the GluR delta subfamily in cerebellar Purkinje cells prompted us to examine its possible physiological roles by the gene targeting technique. Analyses of the GluR delta 2 mutant mice reveal that the delta 2 subunit plays important roles in motor coordination, formation of parallel fiber-Purkinje cell synapses and climbing fiber-Purkinje cell synapses, and long-term depression of parallel fiber-Purkinje cell synaptic transmission. These results suggest a close relationship between synaptic plasticity and synapse formation in the cerebellum.

Activation and Involvement of p38 Mitogen-activated Protein Kinase in Glutamate-induced Apoptosis in Rat Cerebellar Granule Cells

In the mammalian central nervous system glutamate is the major excitatory neurotransmitter and plays a crucial role in plasticity and toxicity of certain neural cells. We found that glutamate stimulated activation of p38 and stress-activated protein kinase (SAPK, also known as c-Jun N-terminal kinase (JNK)), two subgroup members of the mitogen-activated protein kinase superfamily in matured cerebellar granule cells. The p38 activation was largely mediated by N-methyl-d-aspartate receptors. Furthermore, we have revealed a novel signaling pathway, that is, Ca2+-mediated activation of p38 in glutamate-treated granule cells. The glutamate concentration effective for inducing apoptosis correlated with that for inducing p38 activation. SB203580, a specific inhibitor for p38, inhibited glutamate-induced apoptosis. Thus p38 might be involved in glutamate-induced apoptosis in cerebellar granule cells.

Antibodies inactivating mGluR1 metabotropic glutamate receptor block long-term depression in cultured Purkinje cells

Antibodies were raised against two distinct extracellular sequences of the rat mGluR1 metabotropic glutamate receptor expressed as bacterial fusion proteins. Both antibodies specifically reacted with mGluR1 in the rat cerebellum and inhibited the mGluR1 activity as assessed by the analysis of glutamate-stimulated inositol phosphate formation in CHO cells expressing mGluR1. Using these antibodies, we examined the role of mGluR1 in the induction of long-term depression in cultured Purkinje cells. In voltage-clamped Purkinje cells, current induced by iontophoretically applied glutamate was persistently depressed by depolarization of the Purkinje cells in conjunction with the glutamate application. The mGluR1 antibodies completely blocked the depression of glutamate-induced current. The results indicate that activation of mGluR1 is necessary for the induction of cerebellar long-term depression and that these mGluR1 antibodies can be used as selective antagonists.

Ablation of cerebellar Golgi cells disrupts synaptic integration involving GABA inhibition and NMDA receptor activation in motor coordination.

The role of inhibitory Golgi cells in cerebellar function was investigated by selectively ablating Golgi cells expressing human interleukin-2 receptor alpha subunit in transgenic mice, using the immunotoxin-mediated cell targeting technique. Golgi cell disruption caused severe acute motor disorders. These mice showed gradual recovery but retained a continuing inability to perform compound movements. Optical and electrical recordings combined with immunocytological analysis indicated that elimination of Golgi cells not only reduces GABA-mediated inhibition but also attenuates functional NMDA receptors in granule cells. These results demonstrate that synaptic integration involving both GABA inhibition and NMDA receptor activation is essential for compound motor coordination. Furthermore, this integration can adapt after Golgi cell elimination so as not to evoke overexcitation by the reduction of NMDA receptors.

DNER acts as a neuron-specific Notch ligand during Bergmann glial development

Differentiation of CNS glia is regulated by Notch signaling through neuron-glia interaction. Here, we identified Delta/Notch-like EGF-related receptor (DNER), a neuron-specific transmembrane protein, as a previously unknown ligand of Notch during cellular morphogenesis of Bergmann glia in the mouse cerebellum. DNER binds to Notch1 at cell-cell contacts and activates Notch signaling in vitro. In the developing cerebellum, DNER is highly expressed in Purkinje cell dendrites, which are tightly associated with radial fibers of Bergmann glia expressing Notch. DNER specifically binds to Bergmann glia in culture and induces process extension by activating γ-secretase– and Deltex-dependent Notch signaling. Inhibition of Deltex-dependent, but not RBP-J–dependent, Notch signaling in Bergmann glia suppresses formation and maturation of radial fibers in organotypic slice cultures. Additionally, deficiency of DNER retards the formation of radial fibers and results in abnormal arrangement of Bergmann glia. Thus, DNER mediates neuron-glia interaction and promotes morphological differentiation of Bergmann glia through Deltex-dependent Notch signaling.

Depression and potentiation of the synaptic transmission between a granule cell and a Purkinje cell in rat cerebellar culture

Both the depression and the potentiation of synaptic transmission between a cerebellar granule cell and a Purkinje cell, which are considered the cellular basis of motor learning, were established in a simple culture preparation. The repetitive stimulation of both a granule cell and an inferior-olivary neuron depressed the synaptic transmission, and the repetitive stimulation of only a granule cell potentiated the transmission. Thus, a simple model system, where detailed analysis of molecular and cellular mechanisms of synaptic plasticities can be performed, has been established.

Microtubule-based nuclear movement occurs independently of centrosome positioning in migrating neurons.

During neuronal migration in the developing brain, it is thought that the centrosome precedes the nucleus and provides a cue for nuclear migration along the microtubules. In time-lapse imaging studies of radially migrating granule cells in mouse cerebellar slices, we observed that the movements of the nucleus and centrosome appeared to occur independently of each other. The nucleus often migrated ahead of the centrosome during its saltatory movement, negating the supposed role of the centrosome in pulling the nucleus. The nucleus was associated with dynamic microtubules enveloping the entire nucleus and stable microtubules extending from the leading process to the anterior part of the nucleus. Neither of these perinuclear microtubules converged at the centrosome. Disruption or excess formation of stable microtubules attenuated nuclear migration, indicating that the configuration of stable microtubules is crucial for nuclear migration. The inhibition of LIS1 function, a regulator of a microtubule motor dynein, specifically blocks nuclear migration without affecting the coupling of the centrosome and microtubules in the leading process, suggesting that movements of the nucleus and centrosome are differentially regulated by dynein motor function. Thus, the nucleus moves along the microtubules independently of the position of the centrosome in migrating neurons.

Evidence for Activity-Dependent Cortical Wiring: Formation of Interhemispheric Connections in Neonatal Mouse Visual Cortex Requires Projection Neuron Activity

Neuronal activity plays a pivotal role in shaping neuronal wiring. We investigated the role of neuronal activity in the formation of interhemispheric (callosal) axon projections in neonatal mouse visual cortex. Axonal labeling with enhanced green fluorescent protein (GFP) was used to demonstrate spatially organized pattern of callosal projections: GFP-labeled callosal axons from one hemisphere projected densely to a narrowly restricted region at the border between areas 17 and 18 in the contralateral hemisphere, in which they terminated in layers 1–3 and 5. This region- and layer-specific innervation pattern developed by postnatal day 15 (P15). To explore the role of neuronal activity of presynaptic and postsynaptic neurons in callosal connection development, an inwardly rectifying potassium channel, Kir2.1, was expressed in callosal projection neurons and their target postsynaptic neurons. Kir2.1 overexpression reduced the firing rate of cortical neurons. Kir2.1 overexpression in callosal projection neurons disturbed the growth of axons and their arbors that normally occurs between P7 and P13, whereas that in postsynaptic neurons had limited effect on the pattern of presynaptic callosal axon innervation. In addition, exogenous expression of a gain-of-function Kir2.1 mutant channel found in patients with a familial heart disease caused severe deficits in callosal axon projections. These results suggest that projection neuron activity plays a crucial role in interhemispheric connection development and that enhanced Kir2.1 activity can affect cortical wiring.

Opposing roles in neurite growth control by two seven-pass transmembrane cadherins

The growth of neurites (axon and dendrite) should be appropriately regulated by their interactions in the development of nervous systems where a myriad of neurons and their neurites are tightly packed. We show here that mammalian seven-pass transmembrane cadherins Celsr2 and Celsr3 are activated by their homophilic interactions and regulate neurite growth in an opposing manner. Both gene-silencing and coculture assay with rat neuron cultures showed that Celsr2 enhanced neurite growth, whereas Celsr3 suppressed it, and that their opposite functions were most likely the result of a difference of a single amino acid residue in the transmembrane domain. Together with calcium imaging and pharmacological analyses, our results suggest that Celsr2 and Celsr3 fulfill their functions through second messengers, and that differences in the activities of the homologs results in opposite effects in neurite growth regulation.

Suppression of LTD in cultured Purkinje cells deficient in the glutamate receptor δ2 subunit

Involvement of the glutamate receptor channel delta 2 subunit in cerebellar long-term depression (LTD) was studied in cultures prepared from wild-type and mutant mice deficient in the delta 2 subunit. LTD of the glutamate response was induced by pairing glutamate applications and depolarization of a Purkinje cell in wild-type culture. However, in cultured Purkinje cells prepared from mutant mice, the same conditioning failed to induce LTD. Immunocytological staining showed that mutant Purkinje cells develop and express calbindin (a marker protein for Purkinje cells) as do wild-type cells, but they express no delta 2 subunit protein. The results indicate that the glutamate receptor channel delta 2 subunit is involved in the postsynaptic down-regulation of glutamate sensitivity, presumably during cerebellar LTD.