Mineko Kengaku

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.

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.

Inhibition of calpain increases LIS1 expression and partially rescues in vivo phenotypes in a mouse model of lissencephaly

Lissencephaly is a devastating neurological disorder caused by defective neuronal migration. LIS1 (official symbol PAFAH1B1, for platelet-activating factor acetylhydrolase, isoform 1b, subunit 1) was identified as the gene mutated in individuals with lissencephaly, and it was found to regulate cytoplasmic dynein function and localization. Here we show that inhibition or knockdown of calpains protects LIS1 from proteolysis, resulting in the augmentation of LIS1 amounts in Lis1+/− mouse embryonic fibroblast cells and rescue of the aberrant distribution of cytoplasmic dynein, mitochondria and β-COP–positive vesicles. We also show that calpain inhibitors improve neuronal migration of Lis1+/− cerebellar granular neurons. Intraperitoneal injection of the calpain inhibitor ALLN to pregnant Lis1+/− dams rescued apoptotic neuronal cell death and neuronal migration defects in Lis1+/− offspring. Furthermore, in utero knockdown of calpain by short hairpin RNA rescued defective cortical layering in Lis1+/− mice. Thus, calpain inhibition is a potential therapeutic intervention for lissencephaly.

Targeted disruption of Sept3, a heteromeric assembly partner of Sept5 and Sept7 in axons, has no effect on developing CNS neurons.

The septins constitute a family of GTPase proteins that are involved in many cytological processes such as cytokinesis and exocytosis. Previous studies have indicated that mammalian Sept3 is a brain‐specific protein that is abundant in synaptic terminals. Here, we further investigated the localization and function of Sept3 in the mouse brain. Sept3 is expressed in several types of post‐mitotic neurons, including granule cells in the cerebellum and pyramidal neurons in the cerebral cortex and hippocampus. In primary cultures of hippocampal pyramidal neurons, Sept3 protein is enriched at the tips of growing neurites during differentiation. Sept3 directly binds to Sept5 and Sept7 and forms a heteromeric complex at nerve terminals adjacent to where a synaptic vesicle marker, synaptophysin, is expressed in mature neurons. When over‐expressed in HEK293 cells, Sept3 forms filamentous structures that are dependent on the presence of its GTP‐ and phosphoinositide‐binding domains. To investigate the physiological roles of Sept3, we generated Sept3 deficient mice. These mice show no apparent abnormalities in histogenesis nor neuronal differentiation in culture. Expression of synaptic proteins and other septins are unaltered, indicating that Sept3 is dispensable for normal neuronal development.

Long‐term potentiation of mGluR1 activity by depolarization‐induced Homer1a in mouse cerebellar Purkinje neurons

Metabotropic glutamate receptor 1 (mGluR1) plays a crucial role in synaptic plasticity and motor learning in the cerebellum. We have studied activity‐dependent changes in mGluR1 function in mouse cultured Purkinje neurons. Depolarizing stimulation potentiated Ca2+ and current responses to an mGluR1 agonist for several hours in the cultured Purkinje neurons. It also blocked internalization of mGluR1 and increased the number of mGluR1s on the cell membrane. We found that depolarization simultaneously increased transcription of Homer1a in Purkinje neurons. Homer1a inhibited internalization and increased cell‐surface expression of mGluR1 when coexpressed in human embryonic kidney (HEK)‐293 cells. Depolarization‐induced Homer1a expression in Purkinje neurons was blocked by a mitogen‐activated protein kinase (MAPK) inhibitor. Changes in internalization and mGluR1‐mediated Ca2+ response were also blocked by inhibition of MAPK activity, suggesting that localization and activity of mGluR1 were regulated in the same signalling pathway as Homer1a expression. It is thus suggested that depolarization of the Purkinje neuron leads to the increment in mGluR1 responsiveness through MAPK activity and induction of Homer1a expression, which increases active mGluR1 on the cell surface by blocking internalization of mGluR1.

Impaired cerebellar functions in mutant mice lacking DNER.

DNER is a transmembrane protein carrying extracellular EGF repeats and is strongly expressed in Purkinje cells (PCs) in the cerebellum. Current study indicated that DNER functions as a new Notch ligand and mediates the functional communication via cell-cell interaction. By producing and analyzing knockout mice lacking DNER, we demonstrate its essential roles in functional and morphological maturation of the cerebellum. The knockout mice exhibited motor discoordination in the fixed bar and rota-rod tests. The cerebellum from the knockout mice showed significant retardation in morphogenesis and persistent abnormality in fissure organization. Histochemical and electrophysiological analyses detected that PCs retained multiple innervations from climbing fibers (CFs) in the mutant cerebellum. Synaptic transmission from parallel fibers (PFs) or CFs to PCs was apparently normal, while glutamate clearance at the PF-PC synapses was significantly impaired in the mutant mice. Moreover, the protein level of GLAST, the glutamate transporter predominantly expressed in Bergmann glia (BG), was reduced in the mutant cerebellum. Our results indicate that DNER takes part in stimulation of BG maturation via intercellular communication and is essential for precise cerebellar development.

Remodeling of Monoplanar Purkinje Cell Dendrites during Cerebellar Circuit Formation.

Dendrite arborization patterns are critical determinants of neuronal connectivity and integration. Planar and highly branched dendrites of the cerebellar Purkinje cell receive specific topographical projections from two major afferent pathways; a single climbing fiber axon from the inferior olive that extend along Purkinje dendrites, and parallel fiber axons of granule cells that contact vertically to the plane of dendrites. It has been believed that murine Purkinje cell dendrites extend in a single parasagittal plane in the molecular layer after the cell polarity is determined during the early postnatal development. By three-dimensional confocal analysis of growing Purkinje cells, we observed that mouse Purkinje cells underwent dynamic dendritic remodeling during circuit maturation in the third postnatal week. After dendrites were polarized and flattened in the early second postnatal week, dendritic arbors gradually expanded in multiple sagittal planes in the molecular layer by intensive growth and branching by the third postnatal week. Dendrites then became confined to a single plane in the fourth postnatal week. Multiplanar Purkinje cells in the third week were often associated by ectopic climbing fibers innervating nearby Purkinje cells in distinct sagittal planes. The mature monoplanar arborization was disrupted in mutant mice with abnormal Purkinje cell connectivity and motor discoordination. The dendrite remodeling was also impaired by pharmacological disruption of normal afferent activity during the second or third postnatal week. Our results suggest that the monoplanar arborization of Purkinje cells is coupled with functional development of the cerebellar circuitry.

Sonic hedgehog signaling regulates actin cytoskeleton via Tiam1-Rac1 cascade during spine formation.

The sonic hedgehog (Shh) pathway has essential roles in several processes during development of the vertebrate central nervous system (CNS). Here, we report that Shh regulates dendritic spine formation in hippocampal pyramidal neurons via a novel pathway that directly regulates the actin cytoskeleton. Shh signaling molecules Patched (Ptc) and Smoothened (Smo) are expressed in several types of postmitotic neurons, including cerebellar Purkinje cells and hippocampal pyramidal neurons. Knockdown of Smo induces dendritic spine formation in cultured hippocampal neurons independently of Gli-mediated transcriptional activity. Smo interacts with Tiam1, a guanine nucleotide exchange factor for Rac1, via its cytoplasmic C-terminal region. Inhibition of Tiam1 or Rac1 activity suppresses spine induction by Smo knockdown. Shh induces remodeling of the actin cytoskeleton independently of transcriptional activation in mouse embryonic fibroblasts. These findings demonstrate a novel Shh pathway that regulates the actin cytoskeleton via Tiam1-Rac1 activation.

Principles of branch dynamics governing shape characteristics of cerebellar Purkinje cell dendrites

Neurons develop dendritic arbors in cell type-specific patterns. Using growing Purkinje cells in culture as a model, we performed a long-term time-lapse observation of dendrite branch dynamics to understand the rules that govern the characteristic space-filling dendrites. We found that dendrite architecture was sculpted by a combination of reproducible dynamic processes, including constant tip elongation, stochastic terminal branching, and retraction triggered by contacts between growing dendrites. Inhibition of protein kinase C/protein kinase D signaling prevented branch retraction and significantly altered the characteristic morphology of long proximal segments. A computer simulation of dendrite branch dynamics using simple parameters from experimental measurements reproduced the time-dependent changes in the dendrite configuration in live Purkinje cells. Furthermore, perturbation analysis to parameters in silico validated the important contribution of dendritic retraction in the formation of the characteristic morphology. We present an approach using live imaging and computer simulations to clarify the fundamental mechanisms of dendrite patterning in the developing brain.

Dual phases of migration of cerebellar granule cells guided by axonal and dendritic leading processes

During lamination of the cerebellar cortex, granule cells initially migrate tangentially along the external granule layer, and then make a vertical turn and migrate radially to the internal granule layer. We comparatively analyzed the properties of biphasic migration of granule cells in a microexplant culture in which quantitation of morphology and subcellular localization of molecules were readily accomplished. Tangential migration was guided by a leading process that later formed a parallel fiber axon. Translocation of the soma within the axonal process occurred independently of the rapid displacement of the large growth cone. On the other hand, radial migration was guided by a leading process that differentiated into a dendrite after completion of migration. Displacement of the soma and the tiny growth cone were linked so that the radial leading process adopted locomotion and kept a constant length. We propose that the dual phases of granule cell migration are achieved by distinct cellular mechanisms guided by the leading processes forming an axon and a dendrite, respectively.