Your search keyword '"Awasaki T"' showing total 10 results

1. Diverse neuronal lineages make stereotyped contributions to the Drosophila locomotor control center, the central complex.

Author

Yang JS, Awasaki T, Yu HH, He Y, Ding P, Kao JC, and Lee T

Subjects

Animals, Animals, Genetically Modified, CD8 Antigens metabolism, Cell Lineage physiology, Drosophila, Drosophila Proteins genetics, Drosophila Proteins metabolism, Larva, Luminescent Proteins genetics, Luminescent Proteins metabolism, Nerve Net metabolism, Neurons cytology, Brain cytology, Brain growth & development, Locomotion physiology, Nerve Net growth & development, Neural Stem Cells physiology, Neurons physiology

Abstract

The Drosophila central brain develops from a fixed number of neuroblasts. Each neuroblast makes a clone of neurons that exhibit common trajectories. Here we identified 15 distinct clones that carry larval-born neurons innervating the Drosophila central complex (CX), which consists of four midline structures including the protocerebral bridge (PB), fan-shaped body (FB), ellipsoid body (EB), and noduli (NO). Clonal analysis revealed that the small-field CX neurons, which establish intricate projections across different CX substructures, exist in four isomorphic groups that respectively derive from four complex posterior asense-negative lineages. In terms of the region-characteristic large-field CX neurons, we found that two lineages make PB neurons, 10 lineages produce FB neurons, three lineages generate EB neurons, and two lineages yield NO neurons. The diverse FB developmental origins reflect the discrete input pathways for different FB subcompartments. Clonal analysis enlightens both development and anatomy of the insect locomotor control center., (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2013

2. 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

3. Orphan nuclear receptors control neuronal remodeling during fly metamorphosis.

Author

Awasaki T and Lee T

Subjects

Animals, Brain growth & development, Brain physiology, Models, Neurological, Receptors, Steroid physiology, DNA-Binding Proteins physiology, Drosophila physiology, Drosophila Proteins physiology, Metamorphosis, Biological physiology, Neurons physiology, Orphan Nuclear Receptors physiology, Transcription Factors physiology

Published

2011

4. Targeting expression to projection neurons that innervate specific mushroom body calyx and antennal lobe glomeruli in larval Drosophila.

Author

Masuda-Nakagawa LM, Awasaki T, Ito K, and O'Kane CJ

Subjects

Animals, Arthropod Antennae innervation, Dendrites genetics, Dendrites metabolism, Drosophila metabolism, Larva genetics, Larva metabolism, Mushroom Bodies metabolism, Olfactory Nerve growth & development, DNA-Binding Proteins genetics, Drosophila genetics, Drosophila growth & development, Genes, Reporter, Mushroom Bodies innervation, Neurons metabolism, Olfactory Pathways metabolism, Olfactory Receptor Neurons metabolism, Saccharomyces cerevisiae Proteins genetics, Transcription Factors genetics

Abstract

The first and secondary olfactory centers in the olfactory pathway in Drosophila are organized into neuropil structures called glomeruli. The antennal lobe (AL), the first olfactory center in larval Drosophila, is organized in 21 glomeruli. Each AL glomerulus receives innervation from a specific olfactory sensory neuron (OSN), and is therefore identifiable anatomically by the position of the OSN terminal. Olfactory projection neurons (PNs) send a dendrite to a single AL glomerulus and an axon that usually terminates in a single glomerulus in the mushroom body (MB) calyx, a secondary olfactory center, and in the lateral horn. By random labeling of single PNs that express GH146-GAL4, it was previously shown that PNs stereotypically innervate specific AL and calyx glomeruli, and most of these connections have been mapped. Here we report the pattern of innervation of GAL4 lines that drive expression of reporter genes in single or a few PNs, including PNs not identified by the widely used GH146-GAL4 driver. We have mapped the AL and calyx glomeruli innervated by these labeled PNs. This study provides a collection of GAL4 lines to molecularly mark the connections between specific AL and calyx glomeruli. It thus confirms and extends the previous map of AL-calyx connectivity that was based only on randomly labeled single PNs, and provides tools for targeted manipulation of specific PNs for developmental and functional studies., (Copyright © 2010 Elsevier B.V. All rights reserved.)

Published

2010

5. Gamma-aminobutyric acid (GABA)-mediated neural connections in the Drosophila antennal lobe.

Author

Okada R, Awasaki T, and Ito K

Subjects

Animals, Brain physiology, Drosophila Proteins metabolism, Gene Expression, Glutamate Decarboxylase metabolism, Immunohistochemistry, In Situ Hybridization, Fluorescence, Microscopy, Confocal, Neurons cytology, RNA, Messenger metabolism, Receptors, GABA-A metabolism, Receptors, GABA-B metabolism, Synapses metabolism, gamma-Aminobutyric Acid metabolism, Drosophila melanogaster physiology, Neurons metabolism

Abstract

Inhibitory synaptic connections mediated by gamma-aminobutyric acid (GABA) play important roles in the neural computation of the brain. To obtain a detailed overview of the neural connections mediated by GABA signals, we analyzed the distribution of the cells that produce and receive GABA in the Drosophila adult brain. Relatively small numbers of the cells, which form clusters in several areas of the brain, express the GABA synthesis enzyme Gad1. On the other hand, many cells scattered across the brain express ionotropic GABA(A) receptor subunits (Lcch3 and Rdl) and metabotropic GABA(B) receptor subtypes (GABA-B-R1, -2, and -3). To analyze the expression of these genes in distinct identified cell types, we focused on the antennal lobe, where GABAergic neurons play important roles in odor coding. By combining fluorescent in situ hybridization and immunolabeling against GFP expressed with cell-type-specific GAL4 driver strains, we quantified the percentage of the cells that produce or receive GABA for each cell type. GABA was synthesized in the middle antennocerebral tract (mACT) projection neurons and two types of local neurons. Among them, mACT neurons had few presynaptic sites in the antennal lobe, making the local neurons essentially the sole provider of GABA signals there. On the other hand, not only these local neurons but also all types of projection neurons expressed both ionotropic and metabotropic GABA receptors. Thus, even though inhibitory signals are released from only a few, specific types of local neurons, the signals are read by most of the neurons in the antennal lobe neural circuitry.

Published

2009

6. 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

7. 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

8. Gradients of the Drosophila Chinmo BTB-zinc finger protein govern neuronal temporal identity.

Author

Zhu S, Lin S, Kao CF, Awasaki T, Chiang AS, and Lee T

Subjects

5' Untranslated Regions genetics, Amino Acid Sequence, Animals, Brain metabolism, Cell Differentiation, Cell Lineage, Drosophila Proteins chemistry, Drosophila Proteins genetics, Gene Expression Regulation, Developmental, Larva cytology, Larva metabolism, Molecular Sequence Data, Morphogenesis, Mushroom Bodies cytology, Mushroom Bodies metabolism, Mutation, Nerve Tissue Proteins genetics, Time Factors, Transgenes, Brain cytology, Drosophila growth & development, Drosophila Proteins metabolism, Nerve Tissue Proteins metabolism, Neurons metabolism, Protein Processing, Post-Translational, Zinc Fingers

Abstract

Many neural progenitors, including Drosophila mushroom body (MB) and projection neuron (PN) neuroblasts, sequentially give rise to different subtypes of neurons throughout development. We identified a novel BTB-zinc finger protein, named Chinmo (Chronologically inappropriate morphogenesis), that governs neuronal temporal identity during postembryonic development of the Drosophila brain. In both MB and PN lineages, loss of Chinmo autonomously causes early-born neurons to adopt the fates of late-born neurons from the same lineages. Interestingly, primarily due to a posttranscriptional control, MB neurons born at early developmental stages contain more abundant Chinmo than their later-born siblings. Further, the temporal identity of MB progeny can be transformed toward earlier or later fates by reducing or increasing Chinmo levels, respectively. Taken together, we suggest that a temporal gradient of Chinmo (Chinmo(high) --> Chinmo(low)) helps specify distinct birth order-dependent cell fates in an extended neuronal lineage.

Published

2006

9. Integration of chemosensory pathways in the Drosophila second-order olfactory centers.

Author

Tanaka NK, Awasaki T, Shimada T, and Ito K

Subjects

Animals, Cluster Analysis, Drosophila, Female, Immunohistochemistry, Odorants, Olfactory Receptor Neurons physiology, Mushroom Bodies anatomy & histology, Neurons physiology, Olfactory Pathways anatomy & histology, Olfactory Pathways physiology, Smell physiology

Abstract

Background: Behavioral responses to odorants require neurons of the higher olfactory centers to integrate signals detected by different chemosensory neurons. Recent studies revealed stereotypic arborizations of second-order olfactory neurons from the primary olfactory center to the secondary centers, but how third-order neurons read this odor map remained unknown., Results: Using the Drosophila brain as a model system, we analyzed the connectivity patterns between second-order and third-order olfactory neurons. We first isolated three common projection zones in the two secondary centers, the mushroom body (MB) and the lateral horn (LH). Each zone receives converged information via second-order neurons from particular subgroups of antennal-lobe glomeruli. In the MB, third-order neurons extend their dendrites across various combinations of these zones, and axons of this heterogeneous population of neurons converge in the output region of the MB. In contrast, arborizations of the third-order neurons in the LH are constrained within a zone. Moreover, different zones of the LH are linked with different brain areas and form preferential associations between distinct subsets of antennal-lobe glomeruli and higher brain regions., Conclusions: MB is known to be an indispensable site for olfactory learning and memory, whereas LH function is reported to be sufficient for mediating direct nonassociative responses to odors. The structural organization of second-order and third-order neurons suggests that MB is capable of integrating a wide range of odorant information across glomeruli, whereas relatively little integration between different subsets of the olfactory signal repertoire is likely to occur in the LH.

Published

2004

10. An enhanced mutant of red fluorescent protein DsRed for double labeling and developmental timer of neural fiber bundle formation.

Author

Verkhusha VV, Otsuna H, Awasaki T, Oda H, Tsukita S, and Ito K

Subjects

Animals, Animals, Genetically Modified, Cell Line, Drosophila, Escherichia coli metabolism, Green Fluorescent Proteins, Larva metabolism, Microscopy, Confocal methods, Photoreceptor Cells, Invertebrate embryology, Plasmids metabolism, Spectrophotometry, Temperature, Time Factors, Luminescent Proteins genetics, Luminescent Proteins metabolism, Microscopy, Fluorescence methods, Mutation, Neurons metabolism

Abstract

We developed a new variant of coral-derived red fluorescent protein, DsRed S197Y, which is brighter and essentially free from secondary fluorescence peak. This makes it an ideal reporter for double labeling with green fluorescent protein (GFP). Though purified protein shows only 20% stronger fluorescence emission, culture cells that express DsRed S197Y exhibit a 3-3.5 times higher level of fluorescence than the cells that express wild-type DsRed. The much slower fluorescence maturation of DsRed than that of GFP is a beneficial feature for a fluorescent developmental timer application. When GFP and DsRed S197Y are expressed simultaneously, emissions start at different latency. This provides information about the time after the onset of expression. It reflects the order of cell differentiation if the expression is activated upon differentiation of certain types of cells. We applied this system to the developing brain of Drosophila and visualized, for the first time, the formation order of neural fibers within a large bundle. Our results showed that newly extending fibers of the mushroom body neurons mainly run into the core rather than to the periphery of the existing bundle. DsRed-based timer thus presents an indispensable tool for developmental biology and genetics of model organisms.

Published

2001