Your search keyword '"Matsuzaki, F"' showing total 9 results

1. Dmrt factors determine the positional information of cerebral cortical progenitors via differential suppression of homeobox genes.

Author

Konno D, Kishida C, Maehara K, Ohkawa Y, Kiyonari H, Okada S, and Matsuzaki F

Subjects

Animals, Cells, Cultured, Cerebral Cortex cytology, Homeodomain Proteins biosynthesis, Homeodomain Proteins metabolism, Mice, Mice, Inbred C57BL, Mice, Knockout, PAX6 Transcription Factor biosynthesis, PAX6 Transcription Factor metabolism, RNA Interference, RNA, Small Interfering genetics, Cerebral Cortex embryology, Neural Stem Cells cytology, Neurogenesis physiology, Transcription Factors genetics, Transcription Factors metabolism

Abstract

The spatiotemporal identity of neural progenitors and the regional control of neurogenesis are essential for the development of cerebral cortical architecture. Here, we report that mammalian DM domain factors (Dmrt) determine the identity of cerebral cortical progenitors. Among the Dmrt family genes expressed in the developing dorsal telencephalon, Dmrt3 and Dmrta2 show a medial high /lateral low expression gradient. Their simultaneous loss confers a ventral identity to dorsal progenitors, resulting in the ectopic expression of Gsx2 and massive production of GABAergic olfactory bulb interneurons in the dorsal telencephalon. Furthermore, double-mutant progenitors in the medial region exhibit upregulated Pax6 and more lateral characteristics. These ventral and lateral shifts in progenitor identity depend on Dmrt gene dosage. We also found that Dmrt factors bind to Gsx2 and Pax6 enhancers to suppress their expression. Our findings thus reveal that the graded expression of Dmrt factors provide positional information for progenitors by differentially repressing downstream genes in the developing cerebral cortex., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2019. Published by The Company of Biologists Ltd.)

Published

2019

2. Correction: Prdm16 is crucial for progression of the multipolar phase during neural differentiation of the developing neocortex.

Author

Inoue M, Iwai R, Tabata H, Konno D, Komabayashi-Suzuki M, Watanabe C, Iwanari H, Mochizuki Y, Hamakubo T, Matsuzaki F, Nagata KI, and Mizutani KI

Published

2017

3. Prdm16 is crucial for progression of the multipolar phase during neural differentiation of the developing neocortex.

Author

Inoue M, Iwai R, Tabata H, Konno D, Komabayashi-Suzuki M, Watanabe C, Iwanari H, Mochizuki Y, Hamakubo T, Matsuzaki F, Nagata KI, and Mizutani KI

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors genetics, Basic Helix-Loop-Helix Transcription Factors physiology, Cell Differentiation genetics, Cell Differentiation physiology, Cell Movement genetics, Cell Movement physiology, Cells, Cultured, DNA-Binding Proteins antagonists & inhibitors, DNA-Binding Proteins genetics, Female, Gene Expression Regulation, Developmental, Gene Knockdown Techniques, Mice, Mice, Inbred ICR, Mice, Transgenic, Mitochondria metabolism, Neocortex cytology, Neocortex physiology, Neurogenesis genetics, Neurogenesis physiology, Oxidation-Reduction, Pregnancy, Reactive Oxygen Species metabolism, Time-Lapse Imaging, Transcription Factors antagonists & inhibitors, Transcription Factors genetics, DNA-Binding Proteins physiology, Neocortex embryology, Neural Stem Cells cytology, Neural Stem Cells physiology, Transcription Factors physiology

Abstract

The precise control of neuronal migration and morphological changes during differentiation is essential for neocortical development. We hypothesized that the transition of progenitors through progressive stages of differentiation involves dynamic changes in levels of mitochondrial reactive oxygen species (mtROS), depending on cell requirements. We found that progenitors had higher levels of mtROS, but that these levels were significantly decreased with differentiation. The Prdm16 gene was identified as a candidate modulator of mtROS using microarray analysis, and was specifically expressed by progenitors in the ventricular zone. However, Prdm16 expression declined during the transition into NeuroD1-positive multipolar cells. Subsequently, repression of Prdm16 expression by NeuroD1 on the periphery of ventricular zone was crucial for appropriate progression of the multipolar phase and was required for normal cellular development. Furthermore, time-lapse imaging experiments revealed abnormal migration and morphological changes in Prdm16-overexpressing and -knockdown cells. Reporter assays and mtROS determinations demonstrated that PGC1α is a major downstream effector of Prdm16 and NeuroD1, and is required for regulation of the multipolar phase and characteristic modes of migration. Taken together, these data suggest that Prdm16 plays an important role in dynamic cellular redox changes in developing neocortex during neural differentiation., (© 2017. Published by The Company of Biologists Ltd.)

Published

2017

4. Developing a de novo targeted knock-in method based on in utero electroporation into the mammalian brain.

Author

Tsunekawa Y, Terhune RK, Fujita I, Shitamukai A, Suetsugu T, and Matsuzaki F

Subjects

Animals, CRISPR-Cas Systems physiology, Green Fluorescent Proteins metabolism, Mice, Brain metabolism, Electroporation methods

Abstract

Genome-editing technology has revolutionized the field of biology. Here, we report a novel de novo gene-targeting method mediated by in utero electroporation into the developing mammalian brain. Electroporation of donor DNA with the CRISPR/Cas9 system vectors successfully leads to knock-in of the donor sequence, such as EGFP, to the target site via the homology-directed repair mechanism. We developed a targeting vector system optimized to prevent anomalous leaky expression of the donor gene from the plasmid, which otherwise often occurs depending on the donor sequence. The knock-in efficiency of the electroporated progenitors reached up to 40% in the early stage and 20% in the late stage of the developing mouse brain. Furthermore, we inserted different fluorescent markers into the target gene in each homologous chromosome, successfully distinguishing homozygous knock-in cells by color. We also applied this de novo gene targeting to the ferret model for the study of complex mammalian brains. Our results demonstrate that this technique is widely applicable for monitoring gene expression, visualizing protein localization, lineage analysis and gene knockout, all at the single-cell level, in developmental tissues., Competing Interests: The authors declare no competing or financial interests., (© 2016. Published by The Company of Biologists Ltd.)

Published

2016

5. Prox1 postmitotically defines dentate gyrus cells by specifying granule cell identity over CA3 pyramidal cell fate in the hippocampus.

Author

Iwano T, Masuda A, Kiyonari H, Enomoto H, and Matsuzaki F

Subjects

Animals, CA3 Region, Hippocampal cytology, CA3 Region, Hippocampal growth & development, Cell Differentiation genetics, Cell Differentiation physiology, Cell Lineage genetics, Cell Lineage physiology, Dentate Gyrus growth & development, Gene Expression Regulation, Developmental, Homeodomain Proteins genetics, Mice, Mice, Knockout, Mice, Transgenic, Mitosis, Neuronal Plasticity genetics, Neuronal Plasticity physiology, Neurons cytology, Neurons metabolism, Tumor Suppressor Proteins deficiency, Tumor Suppressor Proteins genetics, Prospero-Related Homeobox 1 Protein, CA3 Region, Hippocampal metabolism, Dentate Gyrus cytology, Dentate Gyrus metabolism, Homeodomain Proteins metabolism, Pyramidal Cells cytology, Pyramidal Cells metabolism, Tumor Suppressor Proteins metabolism

Abstract

The brain is composed of diverse types of neurons that fulfill distinct roles in neuronal circuits, as manifested by the hippocampus, where pyramidal neurons and granule cells constitute functionally distinct domains: cornu ammonis (CA) and dentate gyrus (DG), respectively. Little is known about how these two types of neuron differentiate during hippocampal development, although a set of transcription factors that is expressed in progenitor cells is known to be required for the survival of granule cells. Here, we demonstrate in mice that Prox1, a transcription factor constitutively expressed in the granule cell lineage, postmitotically functions to specify DG granule cell identity. Postmitotic elimination of Prox1 caused immature DG neurons to lose the granule cell identity and in turn terminally differentiate into the pyramidal cell type manifesting CA3 neuronal identity. By contrast, Prox1 overexpression caused opposing effects on presumptive hippocampal pyramidal cells. These results indicate that the immature DG cell has the potential to become a granule cell or a pyramidal cell, and Prox1 defines the granule cell identity. This bi-potency is lost in mature DG cells, although Prox1 is still required for correct gene expression in DG granule cells. Thus, our data indicate that Prox1 acts as a postmitotic cell fate determinant for DG granule cells over the CA3 pyramidal cell fate and is crucial for maintenance of the granule cell identity throughout the life.

Published

2012

6. Single-cell gene profiling defines differential progenitor subclasses in mammalian neurogenesis.

Author

Kawaguchi A, Ikawa T, Kasukawa T, Ueda HR, Kurimoto K, Saitou M, and Matsuzaki F

Subjects

Animals, Biomarkers metabolism, Cell Lineage genetics, Cluster Analysis, DNA, Complementary genetics, DNA, Complementary metabolism, Embryo, Mammalian cytology, Embryo, Mammalian metabolism, Gene Expression Regulation, Developmental, Immunohistochemistry, In Situ Hybridization, Mammals genetics, Mammals metabolism, Mice, Mice, Inbred Strains, Neurons cytology, Prosencephalon cytology, Receptors, Notch genetics, Receptors, Notch metabolism, Signal Transduction genetics, Stem Cells classification, Gene Expression Profiling, Nervous System metabolism, Neurons metabolism, Organogenesis physiology, Stem Cells metabolism

Abstract

Cellular diversity of the brain is largely attributed to the spatial and temporal heterogeneity of progenitor cells. In mammalian cerebral development, it has been difficult to determine how heterogeneous the neural progenitor cells are, owing to dynamic changes in their nuclear position and gene expression. To address this issue, we systematically analyzed the cDNA profiles of a large number of single progenitor cells at the mid-embryonic stage in mouse. By cluster analysis and in situ hybridization, we have identified a set of genes that distinguishes between the apical and basal progenitors. Despite their relatively homogeneous global gene expression profiles, the apical progenitors exhibit highly variable expression patterns of Notch signaling components, raising the possibility that this causes the heterogeneous division patterns of these cells. Furthermore, we successfully captured the nascent state of basal progenitor cells. These cells are generated shortly after birth from the division of the apical progenitors, and show strong expression of the major Notch ligand delta-like 1, which soon fades away as the cells migrate in the ventricular zone. We also demonstrated that attenuation of Notch signals immediately induces differentiation of apical progenitors into nascent basal progenitors. Thus, a Notch-dependent feedback loop is likely to be in operation to maintain both progenitor populations.

Published

2008

7. Wiring the nervous system: from form to function.

Author

Matsuzaki F and Sampath K

Subjects

Animals, Body Patterning, Drosophila, Humans, Mice, Models, Biological, Models, Neurological, Neurons metabolism, Zebrafish, Developmental Biology, Nervous System embryology

Abstract

The RIKEN Centre for Developmental Biology recently hosted a joint UK-Asian Pacific Developmental Biology Network meeting called 'Development and Emergence of Function in the Nervous System'. The meeting's program, which was organized by James Briscoe and Krishnaswamy VijayRaghavan, covered a spectrum of processes and mechanisms in neurodevelopment, ranging from the patterning of neural tissue to the initiation of a functional nervous system. One idea to have emerged during this meeting is that 'form underlies function'. Here we discuss some of the themes that were addressed and provide a broad impression of what was a highly stimulating and successful conference.

Published

2007

8. Transcription factors Mash-1 and Prox-1 delineate early steps in differentiation of neural stem cells in the developing central nervous system.

Author

Torii Ma, Matsuzaki F, Osumi N, Kaibuchi K, Nakamura S, Casarosa S, Guillemot F, and Nakafuku M

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors, Blotting, Western, Cell Differentiation, Cells, Cultured, Central Nervous System cytology, DNA-Binding Proteins biosynthesis, DNA-Binding Proteins genetics, Homeodomain Proteins biosynthesis, Homeodomain Proteins genetics, In Situ Hybridization, Mice, Mice, Knockout, Rabbits, Rats, Transcription Factors biosynthesis, Transcription Factors genetics, Tumor Suppressor Proteins, Prospero-Related Homeobox 1 Protein, Central Nervous System growth & development, DNA-Binding Proteins physiology, Helix-Loop-Helix Motifs, Homeodomain Proteins physiology, Stem Cells cytology, Transcription Factors physiology

Abstract

Like other tissues and organs in vertebrates, multipotential stem cells serve as the origin of diverse cell types during genesis of the mammalian central nervous system (CNS). During early development, stem cells self-renew and increase their total cell numbers without overt differentiation. At later stages, the cells withdraw from this self-renewal mode, and are fated to differentiate into neurons and glia in a spatially and temporally regulated manner. However, the molecular mechanisms underlying this important step in cell differentiation remain poorly understood. In this study, we present evidence that the expression and function of the neural-specific transcription factors Mash-1 and Prox-1 are involved in this process. In vivo, Mash-1- and Prox-1-expressing cells were defined as a transient proliferating population that was molecularly distinct from self-renewing stem cells. By taking advantage of in vitro culture systems, we showed that induction of Mash-1 and Prox-1 coincided with an initial step of differentiation of stem cells. Furthermore, forced expression of Mash-1 led to the down-regulation of nestin, a marker for undifferentiated neuroepithelial cells, and up-regulation of Prox-1, suggesting that Mash-1 positively regulates cell differentiation. In support of these observations in vitro, we found specific defects in cellular differentiation and loss of expression of Prox-1 in the developing brain of Mash-1 mutant mice in vivo. Thus, we propose that induction of Mash-1 and Prox-1 is one of the critical molecular events that control early development of the CNS.

Published

1999

9. miranda localizes staufen and prospero asymmetrically in mitotic neuroblasts and epithelial cells in early Drosophila embryogenesis.

Author

Matsuzaki F, Ohshiro T, Ikeshima-Kataoka H, and Izumi H

Subjects

Alleles, Animals, Cell Cycle Proteins genetics, Cell Polarity genetics, Drosophila melanogaster cytology, Drosophila melanogaster genetics, Ectoderm cytology, Epithelial Cells cytology, Epithelial Cells metabolism, Ganglia, Invertebrate cytology, Genes, Insect, Immunohistochemistry, In Situ Hybridization, Nerve Tissue Proteins genetics, Neurons cytology, Nuclear Proteins genetics, Sequence Deletion, Stem Cells, Cell Cycle Proteins physiology, Drosophila Proteins, Drosophila melanogaster embryology, Mitosis genetics, Nerve Tissue Proteins metabolism, Neurons metabolism, Nuclear Proteins metabolism, RNA-Binding Proteins metabolism, Transcription Factors

Abstract

When neuroblasts divide, prospero protein and mRNA segregate asymmetrically into the daughter neuroblast and sibling ganglion mother cell. miranda is known to localize prospero protein to the basal cell cortex of neuroblasts while the staufen RNA-binding protein mediates prospero mRNA localization. Here we show that miranda is required for asymmetric staufen localization in neuroblasts. Analyses using miranda mutants reveal that prospero and staufen interact with miranda under the same cell-cycle-dependent control. miranda thus acts to partition both prospero protein and mRNA. Furthermore, miranda localizes prospero and staufen to the basolateral cortex in dividing epithelial cells, which express the three proteins prior to neurogenesis. Our observations suggest that the epithelial cell and neuroblast (both of epithelial origin) share the same molecular machinery for creating cellular asymmetry.

Published

1998