Your search keyword '"Awasaki T"' showing total 7 results

1. Multiple lineages enable robust development of the neuropil-glia architecture in adult Drosophila .

Author

Kato K, Orihara-Ono M, and Awasaki T

Subjects

Animals, Brain cytology, Brain embryology, Cell Lineage physiology, Cell Proliferation physiology, DNA-Binding Proteins metabolism, Drosophila melanogaster metabolism, Metamorphosis, Biological genetics, Metamorphosis, Biological physiology, Neurogenesis genetics, Astrocytes cytology, Drosophila Proteins metabolism, Drosophila melanogaster embryology, Nerve Tissue Proteins metabolism, Neurogenesis physiology, Neuropil cytology, Nuclear Proteins metabolism, Protein-Tyrosine Kinases metabolism, Receptors, Fibroblast Growth Factor metabolism, Transcription Factors metabolism

Abstract

Neural remodeling is essential for the development of a functional nervous system and has been extensively studied in the metamorphosis of Drosophila Despite the crucial roles of glial cells in brain functions, including learning and behavior, little is known of how adult glial cells develop in the context of neural remodeling. Here, we show that the architecture of neuropil-glia in the adult Drosophila brain, which is composed of astrocyte-like glia (ALG) and ensheathing glia (EG), robustly develops from two different populations in the larva: the larval EG and glial cell missing -positive ( gcm + ) cells. Whereas gcm + cells proliferate and generate adult ALG and EG, larval EG dedifferentiate, proliferate and redifferentiate into the same glial subtypes. Each glial lineage occupies a certain brain area complementary to the other, and together they form the adult neuropil-glia architecture. Both lineages require the FGF receptor Heartless to proliferate, and the homeoprotein Prospero to differentiate into ALG. Lineage-specific inhibition of gliogenesis revealed that each lineage compensates for deficiency in the proliferation of the other. Together, the lineages ensure the robust development of adult neuropil-glia, thereby ensuring a functional brain., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2020. Published by The Company of Biologists Ltd.)

Published

2020

2. Lineage-guided Notch-dependent gliogenesis by Drosophila multi-potent progenitors.

Author

Ren Q, Awasaki T, Wang YC, Huang YF, and Lee T

Subjects

Animals, Apoptosis physiology, Astrocytes cytology, Brain cytology, Cell Lineage physiology, Cell Proliferation physiology, Neurons cytology, Brain embryology, Drosophila embryology, Drosophila Proteins metabolism, Neural Stem Cells cytology, Neurogenesis physiology, Receptors, Notch metabolism

Abstract

Macroglial cells in the central nervous system exhibit regional specialization and carry out region-specific functions. Diverse glial cells arise from specific progenitors in specific spatiotemporal patterns. This raises an interesting possibility that glial precursors with distinct developmental fates exist that govern region-specific gliogenesis. Here, we have mapped the glial progeny produced by the Drosophila type II neuroblasts, which, like vertebrate radial glia cells, yield both neurons and glia via intermediate neural progenitors (INPs). Distinct type II neuroblasts produce different characteristic sets of glia. A single INP can make both astrocyte-like and ensheathing glia, which co-occupy a relatively restrictive subdomain. Blocking apoptosis uncovers further lineage distinctions in the specification, proliferation and survival of glial precursors. Both the switch from neurogenesis to gliogenesis and the subsequent glial expansion depend on Notch signaling. Taken together, lineage origins preconfigure the development of individual glial precursors with involvement of serial Notch actions in promoting gliogenesis., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2018. Published by The Company of Biologists Ltd.)

Published

2018

3. Concentric zones, cell migration and neuronal circuits in the Drosophila visual center.

Author

Hasegawa E, Kitada Y, Kaido M, Takayama R, Awasaki T, Tabata T, and Sato M

Subjects

Animals, Axons, Dendrites, Drosophila embryology, Retina, Cell Movement, Eye embryology, Neurons physiology

Abstract

The Drosophila optic lobe comprises a wide variety of neurons, which form laminar neuropiles with columnar units and topographic projections from the retina. The Drosophila optic lobe shares many structural characteristics with mammalian visual systems. However, little is known about the developmental mechanisms that produce neuronal diversity and organize the circuits in the primary region of the optic lobe, the medulla. Here, we describe the key features of the developing medulla and report novel phenomena that could accelerate our understanding of the Drosophila visual system. The identities of medulla neurons are pre-determined in the larval medulla primordium, which is subdivided into concentric zones characterized by the expression of four transcription factors: Drifter, Runt, Homothorax and Brain-specific homeobox (Bsh). The expression pattern of these factors correlates with the order of neuron production. Once the concentric zones are specified, the distribution of medulla neurons changes rapidly. Each type of medulla neuron exhibits an extensive but defined pattern of migration during pupal development. The results of clonal analysis suggest homothorax is required to specify the neuronal type by regulating various targets including Bsh and cell-adhesion molecules such as N-cadherin, while drifter regulates a subset of morphological features of Drifter-positive neurons. Thus, genes that show the concentric zones may form a genetic hierarchy to establish neuronal circuits in the medulla.

Published

2011

4. Neuronal programmed cell death induces glial cell division in the adult Drosophila brain.

Author

Kato K, Awasaki T, and Ito K

Subjects

Animals, Axons metabolism, Axons pathology, Brain pathology, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Membrane Proteins metabolism, Molting, Neuroglia metabolism, Neurons metabolism, Apoptosis, Brain cytology, Cell Division, Drosophila melanogaster cytology, Neuroglia cytology, Neurons cytology

Abstract

Although mechanisms that lead to programmed cell death (PCD) in neurons have been analysed extensively, little is known about how surrounding cells coordinate with it. Here we show that neuronal PCD in the Drosophila brain induces glial cell division. We identified PCD in neurons and cell division in glia occurring in a consistent spatiotemporal manner in adult flies shortly after eclosion. Glial division was suppressed when neuronal PCD was inhibited by ectopic expression of the caspase inhibitor gene p35, indicating their causal relationship. Glia also responded to neural injury in a similar manner: both stab injury and degeneration of sensory axons in the brain caused by antennal ablation induced glial division. Eiger, a tumour necrosis factor superfamily ligand, appears to be a link between developmental PCD/neural injury and glial division, as glial division was attenuated in eiger mutant flies. Whereas PCD soon after eclosion occurred in eiger mutants as in the wild type, we observed excess neuronal PCD 2 days later, suggesting a protective function for Eiger or the resulting glial division against the endogenous PCD. In older flies, between 6 and 50 days after adult eclosion, glial division was scarcely observed in the intact brain. Moreover, 8 days after adult eclosion, glial cells no longer responded to brain injury. These results suggest that the life of an adult fly can be divided into two phases: the first week, as a critical period for neuronal cell death-associated glial division, and the remainder.

Published

2009

5. Clonal analysis of Drosophila antennal lobe neurons: diverse neuronal architectures in the lateral neuroblast lineage.

Author

Lai SL, Awasaki T, Ito K, and Lee T

Subjects

Animals, Axons metabolism, Clone Cells, Enhancer Elements, Genetic genetics, Mosaicism, Animal Structures cytology, Cell Lineage, Drosophila melanogaster cytology, Neurons cytology

Abstract

The antennal lobe (AL) is the primary structure in the Drosophila brain that relays odor information from the antennae to higher brain centers. The characterization of uniglomerular projection neurons (PNs) and some local interneurons has facilitated our understanding of olfaction; however, many other AL neurons remain unidentified. Because neuron types are mostly specified by lineage and temporal origins, we use the MARCM techniques with a set of enhancer-trap GAL4 lines to perform systematical lineage analysis to characterize neuron morphologies, lineage origin and birth timing in the three AL neuron lineages that contain GAL4-GH146-positive PNs: anterodorsal, lateral and ventral lineages. The results show that the anterodorsal lineage is composed of pure uniglomerular PNs that project through the inner antennocerebral tract. The ventral lineage produces uniglomerular and multiglomerular PNs that project through the middle antennocerebral tract. The lateral lineage generates multiple types of neurons, including uniglomeurlar PNs, diverse atypical PNs, various types of AL local interneurons and the neurons that make no connection within the ALs. Specific neuron types in all three lineages are produced in specific time windows, although multiple neuron types in the lateral lineage are made simultaneously. These systematic cell lineage analyses have not only filled gaps in the olfactory map, but have also exemplified additional strategies used in the brain to increase neuronal diversity.

Published

2008

6. DPP signaling controls development of the lamina glia required for retinal axon targeting in the visual system of Drosophila.

Author

Yoshida S, Soustelle L, Giangrande A, Umetsu D, Murakami S, Yasugi T, Awasaki T, Ito K, Sato M, and Tabata T

Subjects

Animals, Cell Differentiation, Cell Lineage, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Drosophila Proteins genetics, Drosophila melanogaster cytology, Drosophila melanogaster genetics, Gene Expression Regulation, Developmental, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, Neuroglia metabolism, Optic Lobe, Nonmammalian growth & development, Optic Lobe, Nonmammalian metabolism, Retina abnormalities, Retina growth & development, Smad4 Protein genetics, Smad4 Protein metabolism, Time Factors, Transcription Factors genetics, Transcription Factors metabolism, Axons metabolism, Drosophila Proteins metabolism, Drosophila melanogaster growth & development, Drosophila melanogaster metabolism, Neuroglia cytology, Retina cytology, Retina metabolism, Signal Transduction

Abstract

The Drosophila visual system consists of the compound eyes and the optic ganglia in the brain. Among the eight photoreceptor (R) neurons, axons from the R1-R6 neurons stop between two layers of glial cells in the lamina, the most superficial ganglion in the optic lobe. Although it has been suggested that the lamina glia serve as intermediate targets of R axons, little is known about the mechanisms by which these cells develop. We show that DPP signaling plays a key role in this process. dpp is expressed at the margin of the lamina target region, where glial precursors reside. The generation of clones mutant for Medea, the DPP signal transducer, or inhibition of DPP signaling in this region resulted in defects in R neuron projection patterns and in the lamina morphology, which was caused by defects in the differentiation of the lamina glial cells. glial cells missing/glial cells deficient (gcm; also known as glide) is expressed shortly after glia precursors start to differentiate and migrate. Its expression depends on DPP; gcm is reduced or absent in dpp mutants or Medea clones, and ectopic activation of DPP signaling induces ectopic expression of gcm and REPO. In addition, R axon projections and lamina glia development were impaired by the expression of a dominant-negative form of gcm, suggesting that gcm indeed controls the differentiation of lamina glial cells. These results suggest that DPP signaling mediates the maturation of the lamina glia required for the correct R axon projection pattern by controlling the expression of gcm.

Published

2005

7. Embryonic and larval development of the Drosophila mushroom bodies: concentric layer subdivisions and the role of fasciclin II.

Author

Kurusu M, Awasaki T, Masuda-Nakagawa LM, Kawauchi H, Ito K, and Furukubo-Tokunaga K

Subjects

Animals, Biomarkers, Cell Adhesion Molecules, Neuronal genetics, Drosophila melanogaster genetics, Genes, Insect, Genes, Reporter, Larva growth & development, Larva metabolism, Mushroom Bodies cytology, Neurons cytology, Neurons physiology, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Regulatory Sequences, Nucleic Acid, Cell Adhesion Molecules, Neuronal physiology, Drosophila melanogaster embryology, Drosophila melanogaster growth & development, Gene Expression Regulation, Developmental, Mushroom Bodies embryology, Mushroom Bodies growth & development

Abstract

Mushroom bodies (MBs) are the centers for olfactory associative learning and elementary cognitive functions in the arthropod brain. In order to understand the cellular and genetic processes that control the early development of MBs, we have performed high-resolution neuroanatomical studies of the embryonic and post-embryonic development of the Drosophila MBs. In the mid to late embryonic stages, the pioneer MB tracts extend along Fasciclin II (FAS II)-expressing cells to form the primordia for the peduncle and the medial lobe. As development proceeds, the axonal projections of the larval MBs are organized in layers surrounding a characteristic core, which harbors bundles of actin filaments. Mosaic analyses reveal sequential generation of the MB layers, in which newly produced Kenyon cells project into the core to shift to more distal layers as they undergo further differentiation. Whereas the initial extension of the embryonic MB tracts is intact, loss-of-function mutations of fas II causes abnormal formation of the larval lobes. Mosaic studies demonstrate that FAS II is intrinsically required for the formation of the coherent organization of the internal MB fascicles. Furthermore, we show that ectopic expression of FAS II in the developing MBs results in severe lobe defects, in which internal layers also are disrupted. These results uncover unexpected internal complexity of the larval MBs and demonstrate unique aspects of neural generation and axonal sorting processes during the development of the complex brain centers in the fruit fly brain.

Published

2002