Makoto Masaoka scite author profile

BackgroundCerebellar corticogenesis begins with the assembly of Purkinje cells into the Purkinje plate (PP) by embryonic day 14.5 (E14.5) in mice. Although the dependence of PP formation on the secreted protein Reelin is well known and a prevailing model suggests that Purkinje cells migrate along the 'radial glial' fibers connecting the ventricular and pial surfaces, it is not clear how Purkinje cells behave in response to Reelin to initiate the PP. Furthermore, it is not known what nascent Purkinje cells look like in vivo. When and how Purkinje cells start axonogenesis must also be elucidated.ResultsWe show that Purkinje cells generated on E10.5 in the posterior periventricular region of the lateral cerebellum migrate tangentially, after only transiently migrating radially, towards the anterior, exhibiting an elongated morphology consistent with axonogenesis at E12.5. After their somata reach the outer/dorsal region by E13.5, they change 'posture' by E14.5 through remodeling of non-axon (dendrite-like) processes and a switchback-like mode of somal movement towards a superficial Reelin-rich zone, while their axon-like fibers remain relatively deep, which demarcates the somata-packed portion as a plate. In reeler cerebella, the early born posterior lateral Purkinje cells are initially normal during migration with anteriorly extended axon-like fibers until E13.5, but then fail to form the PP due to lack of the posture-change step.ConclusionsPreviously unknown behaviors are revealed for a subset of Purkinje cells born early in the posteior lateral cerebellum: tangential migration; early axonogenesis; and Reelin-dependent reorientation initiating PP formation. This study provides a solid basis for further elucidation of Reelin's function and the mechanisms underlying the cerebellar corticogenesis, and will contribute to the understanding of how polarization of individual cells drives overall brain morphogenesis.

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Dynamics of Centrosome Translocation and Microtubule Organization in Neocortical Neurons during Distinct Modes of Polarization

Sakakibara

Sato

Ando

et al. 2013

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Neuronal migration and process formation require cytoskeletal organization and remodeling. Recent studies suggest that centrosome translocation is involved in initial axon outgrowth, while the role of centrosomal positioning is not clear. Here, we examine relations between centrosomal positioning, axonogenesis, and microtubule (MT) polarization in multipolar and bipolar neocortical neurons. We monitored dynamic movements of centrosomes and MT plus ends in migratory neurons in embryonic mouse cerebral slices. In locomoting bipolar neurons, the centrosome oriented toward the pia-directed leading process. Bipolar neurons displayed dense MT plus end dynamics in leading processes, while trailing processes showed clear bidirectional MTs. In migrating multipolar neurons, new processes emerged irrespective of centrosome localization, followed by centrosome reorientations toward the dominant process. Anterograde movements of MT plus ends occurred in growing processes and retrograde movements were observed after retraction of the distal tip. In multipolar neurons, axon formed by tangential extension of a dominant process and the centrosome oriented toward the growing axon, while in locomoting neurons, an axon formed opposite to the direction of migration and the centrosome localized to the base of the leading process. Our data suggest that MT organization may alter centrosomal localization and that centrosomal positioning does not necessarily direct process formation.

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Periventricular notch activation and asymmetric Ngn2 and Tbr2 expression in pair-generated neocortical daughter cells

Ochiai

Nakatani

Takahara

et al. 2009

Molecular and Cellular Neuroscience

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Survey of the morphogenetic dynamics of the ventricular surface of the developing mouse neocortex

Imafuku

Saito

Kanda

et al. 2007

Developmental Dynamics

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To understand the morphogenetic dynamics of the inner surface of the embryonic pallial (neocortical) wall, we immunohistochemically surveyed the cellular endfeet facing the lateral ventricle and found that the average endfoot area was minimal at embryonic day (E)12 in mice. This endfoot narrowing at E12 may represent a change in the mode of cell production at the surface from a purely proliferative mode that retains all daughter cells to a more differentiation-directed mode that allows some daughter cells to leave the surface. The apices of cells undergoing mitosis were 1.5-3.9 times larger than the overall cell apices and 6.7-8.7 times smaller than the cross-sectional area of mitotic somata. En face time-lapse monitoring of each endfoot permitted observation of its cell cycle-dependent size changes, division, and relationships with neighboring endfeet. Planar divisions oriented along the lateral-medial axis were less abundant than those oriented along the rostral-caudal axis at E10 and E11, but basal body distribution in each endfoot was random. Developmental Dynamics 236:3061-3070, 2007.

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A possible role of oxidative stress in the switch mechanism of the cell death mode from apoptosis to necrosis – studies on ρ0 cells

et al. 2007

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Makoto Masaoka

Migration, early axonogenesis, and Reelin-dependent layer-forming behavior of early/posterior-born Purkinje cells in the developing mouse lateral cerebellum

Dynamics of Centrosome Translocation and Microtubule Organization in Neocortical Neurons during Distinct Modes of Polarization

Periventricular notch activation and asymmetric Ngn2 and Tbr2 expression in pair-generated neocortical daughter cells

Survey of the morphogenetic dynamics of the ventricular surface of the developing mouse neocortex

A possible role of oxidative stress in the switch mechanism of the cell death mode from apoptosis to necrosis – studies on ρ0 cells

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