Your search keyword '"Otsuna H"' showing total 23 results

1. A searchable image resource of Drosophila GAL4-driver expression patterns with single neuron resolution

Author

Meissner, G.W., Nern, A., Dorman, Z., DePasquale, G.M., Forster, K., Gibney, T., Hausenfluck, J.H., He, Y., Iyer, N.A., Jeter, J., Johnson, L., Johnston, R.M., Lee, K., Melton, B., Yarbrough, B., Zugates, C.T., Clements, Jody, Goina, C., Otsuna, H., Rokicki, K., Svirskas, R.R., Aso, Y., Card, G.M., Dickson, B.J., Ehrhardt, E., Goldammer, J., Ito, M., Kainmueller, D., Korff, W., Mais, L., Minegishi, R., Namiki, S., Rubin, G.M., Sterne, G.R., Wolff, T., and Malkesman, O.

Subjects

Function and Dysfunction of the Nervous System

Abstract

Precise, repeatable genetic access to specific neurons via GAL4/UAS and related methods is a key advantage of Drosophila neuroscience. Neuronal targeting is typically documented using light microscopy of full GAL4 expression patterns, which generally lack the single-cell resolution required for reliable cell type identification. Here we use stochastic GAL4 labeling with the MultiColor FlpOut approach to generate cellular resolution confocal images at large scale. We are releasing aligned images of 74,000 such adult central nervous systems. An anticipated use of this resource is to bridge the gap between neurons identified by electron or light microscopy. Identifying individual neurons that make up each GAL4 expression pattern improves the prediction of split-GAL4 combinations targeting particular neurons. To this end we have made the images searchable on the NeuronBridge website. We demonstrate the potential of NeuronBridge to rapidly and effectively identify neuron matches based on morphology across imaging modalities and datasets.

Published

2023

2. Color depth MIP mask search: a new tool to expedite Split-GAL4 creation

Author

Otsuna H, Kawase T, and Masayoshi Ito

Subjects

animal structures, Computer science, business.industry, media_common.quotation_subject, fungi, Central nervous system, Machine learning, computer.software_genre, Expression (mathematics), medicine.anatomical_structure, Color depth, medicine, Artificial intelligence, Function (engineering), business, computer, media_common

Abstract

The GAL4-UAS system has proven its versatility in studying the function and expression patterns of neurons theDrosophilacentral nervous system. Although the GAL4 system has been used for 25 years, recent genetic intersectional tools have enabled genetic targeting of very small numbers of neurons aiding in the understanding of their function. This split-GAL4 system is extremely powerful for studying neuronal morphology and the neural basis of animal behavior. However, choosing lines to intersect that have overlapping patterns restricted to one to a few neurons has been cumbersome. This challenge is now growing as the collections of GAL4 driver lines has increased. Here we present a new method and software plug-in for Fiji to dramatically improve the speed of querying large databases of potential lines to intersect and aid in the split-GAL4 creation. We also provide pre-computed datasets for the Janelia GAL4 (5,738 lines) and VT GAL4 (7,429 lines) of the Drosophila central nervous system (CNS). The tool reduced our split-GAL4 creation effort dramatically.

Published

2018

3. High-resolution analysis of CNS expression patterns in zebrafish Gal4 enhancer-trap lines

Author

Otsuna, H, Hutcheson, DA, Duncan, RN, McPherson, AD, Scoresby, AN, Gaynes, BF, Tong, Z, Fujimoto, E, Kwan, KM, Chien, CB, and Dorsky, RI

Subjects

Central Nervous System, Neurons, Saccharomyces cerevisiae Proteins, Databases, Factual, Gene Expression Profiling, Gene Expression Regulation, Developmental, Nerve Tissue Proteins, Zebrafish Proteins, Article, Animals, Genetically Modified, DNA-Binding Proteins, Luminescent Proteins, Mutagenesis, Insertional, Enhancer Elements, Genetic, Imaging, Three-Dimensional, Genes, Reporter, Organ Specificity, DNA Transposable Elements, Genes, Synthetic, Animals, Zebrafish, Transcription Factors

Abstract

The application of the Gal4/UAS system to enhancer and gene trapping screens in zebrafish has greatly increased the ability to label and manipulate cell populations in multiple tissues, including the central nervous system (CNS). However the ability to select existing lines for specific applications has been limited by the lack of detailed expression analysis.We describe a Gal4 enhancer trap screen in which we used advanced image analysis, including three-dimensional confocal reconstructions and documentation of expression patterns at multiple developmental time points. In all, we have created and annotated 98 lines exhibiting a wide range of expression patterns, most of which include CNS expression. Expression was also observed in nonneural tissues such as muscle, skin epithelium, vasculature, and neural crest derivatives. All lines and data are publicly available from the Zebrafish International Research Center (ZIRC) from the Zebrafish Model Organism Database (ZFIN).Our detailed documentation of expression patterns, combined with the public availability of images and fish lines, provides a valuable resource for researchers wishing to study CNS development and function in zebrafish. Our data also suggest that many existing enhancer trap lines may have previously uncharacterized expression in multiple tissues and cell types.

Published

2015

4. Processing of Horizontal Optic Flow in Three Visual Interneurons of theDrosophilaBrain

Author

Schnell, B., primary, Joesch, M., additional, Forstner, F., additional, Raghu, S. V., additional, Otsuna, H., additional, Ito, K., additional, Borst, A., additional, and Reiff, D. F., additional

Published

2010

5. An Image Processing Tool for Automated Quantification of Bacterial Burdens in Zebrafish Larvae.

Author

Yamaguchi N, Otsuna H, Eisenberg-Bord M, and Ramakrishnan L

Abstract

Zebrafish larvae are used to model the pathogenesis of multiple bacteria. This transparent model offers the unique advantage of allowing quantification of fluorescent bacterial burdens (fluorescent pixel counts: FPC) in vivo by facile microscopical methods, replacing enumeration of bacteria using time-intensive plating of lysates on bacteriological media. Accurate FPC measurements require laborious manual image processing to mark the outside borders of the animals so as to delineate the bacteria inside the animals from those in the culture medium that they are in. Here, we have developed an automated ImageJ/Fiji-based macro that accurately detect the outside borders of Mycobacterium marinum -infected larvae., Competing Interests: Competing interests The authors declare no competing interest.

Published

2024

6. NeuronBridge: an intuitive web application for neuronal morphology search across large data sets.

Author

Clements J, Goina C, Hubbard PM, Kawase T, Olbris DJ, Otsuna H, Svirskas R, and Rokicki K

Subjects

Animals, Neurons, Microscopy, Electron, Drosophila, Software, Connectome

Abstract

Background: Neuroscience research in Drosophila is benefiting from large-scale connectomics efforts using electron microscopy (EM) to reveal all the neurons in a brain and their connections. To exploit this knowledge base, researchers relate a connectome's structure to neuronal function, often by studying individual neuron cell types. Vast libraries of fly driver lines expressing fluorescent reporter genes in sets of neurons have been created and imaged using confocal light microscopy (LM), enabling the targeting of neurons for experimentation. However, creating a fly line for driving gene expression within a single neuron found in an EM connectome remains a challenge, as it typically requires identifying a pair of driver lines where only the neuron of interest is expressed in both. This task and other emerging scientific workflows require finding similar neurons across large data sets imaged using different modalities., Results: Here, we present NeuronBridge, a web application for easily and rapidly finding putative morphological matches between large data sets of neurons imaged using different modalities. We describe the functionality and construction of the NeuronBridge service, including its user-friendly graphical user interface (GUI), extensible data model, serverless cloud architecture, and massively parallel image search engine., Conclusions: NeuronBridge fills a critical gap in the Drosophila research workflow and is used by hundreds of neuroscience researchers around the world. We offer our software code, open APIs, and processed data sets for integration and reuse, and provide the application as a service at http://neuronbridge.janelia.org ., (© 2024. The Author(s).)

Published

2024

7. Neural circuit mechanisms for transforming learned olfactory valences into wind-oriented movement.

Author

Aso Y, Yamada D, Bushey D, Hibbard KL, Sammons M, Otsuna H, Shuai Y, and Hige T

Subjects

Animals, Drosophila physiology, Smell physiology, Neurons physiology, Mushroom Bodies physiology, Drosophila melanogaster physiology, Wind, Learning

Abstract

How memories are used by the brain to guide future action is poorly understood. In olfactory associative learning in Drosophila , multiple compartments of the mushroom body act in parallel to assign a valence to a stimulus. Here, we show that appetitive memories stored in different compartments induce different levels of upwind locomotion. Using a photoactivation screen of a new collection of split-GAL4 drivers and EM connectomics, we identified a cluster of neurons postsynaptic to the mushroom body output neurons (MBONs) that can trigger robust upwind steering. These UpWind Neurons (UpWiNs) integrate inhibitory and excitatory synaptic inputs from MBONs of appetitive and aversive memory compartments, respectively. After formation of appetitive memory, UpWiNs acquire enhanced response to reward-predicting odors as the response of the inhibitory presynaptic MBON undergoes depression. Blocking UpWiNs impaired appetitive memory and reduced upwind locomotion during retrieval. Photoactivation of UpWiNs also increased the chance of returning to a location where activation was terminated, suggesting an additional role in olfactory navigation. Thus, our results provide insight into how learned abstract valences are gradually transformed into concrete memory-driven actions through divergent and convergent networks, a neuronal architecture that is commonly found in the vertebrate and invertebrate brains., Competing Interests: YA, DY, DB, KH, MS, HO, YS, TH No competing interests declared, (© 2023, Aso et al.)

Published

2023

8. A searchable image resource of Drosophila GAL4 driver expression patterns with single neuron resolution.

Author

Meissner GW, Nern A, Dorman Z, DePasquale GM, Forster K, Gibney T, Hausenfluck JH, He Y, Iyer NA, Jeter J, Johnson L, Johnston RM, Lee K, Melton B, Yarbrough B, Zugates CT, Clements J, Goina C, Otsuna H, Rokicki K, Svirskas RR, Aso Y, Card GM, Dickson BJ, Ehrhardt E, Goldammer J, Ito M, Kainmueller D, Korff W, Mais L, Minegishi R, Namiki S, Rubin GM, Sterne GR, Wolff T, and Malkesman O

Subjects

Animals, Drosophila metabolism, Neurons metabolism, Central Nervous System metabolism, Drosophila melanogaster genetics, Drosophila melanogaster metabolism, Transcription Factors genetics, Transcription Factors metabolism, Drosophila Proteins genetics, Drosophila Proteins metabolism, Neurosciences

Abstract

Precise, repeatable genetic access to specific neurons via GAL4/UAS and related methods is a key advantage of Drosophila neuroscience. Neuronal targeting is typically documented using light microscopy of full GAL4 expression patterns, which generally lack the single-cell resolution required for reliable cell type identification. Here, we use stochastic GAL4 labeling with the MultiColor FlpOut approach to generate cellular resolution confocal images at large scale. We are releasing aligned images of 74,000 such adult central nervous systems. An anticipated use of this resource is to bridge the gap between neurons identified by electron or light microscopy. Identifying individual neurons that make up each GAL4 expression pattern improves the prediction of split-GAL4 combinations targeting particular neurons. To this end, we have made the images searchable on the NeuronBridge website. We demonstrate the potential of NeuronBridge to rapidly and effectively identify neuron matches based on morphology across imaging modalities and datasets., Competing Interests: GM, AN, ZD, GD, KF, TG, JH, YH, NI, JJ, LJ, RJ, KL, BM, BY, CZ, JC, CG, HO, KR, RS, YA, GC, BD, EE, JG, MI, DK, WK, LM, RM, SN, GR, GS, TW, OM No competing interests declared, (© 2023, Meissner et al.)

Published

2023

9. Rapid reconstruction of neural circuits using tissue expansion and light sheet microscopy.

Author

Lillvis JL, Otsuna H, Ding X, Pisarev I, Kawase T, Colonell J, Rokicki K, Goina C, Gao R, Hu A, Wang K, Bogovic J, Milkie DE, Meienberg L, Mensh BD, Boyden ES, Saalfeld S, Tillberg PW, and Dickson BJ

Subjects

Animals, Synapses physiology, Drosophila, Tissue Expansion, Microscopy, Connectome methods

Abstract

Brain function is mediated by the physiological coordination of a vast, intricately connected network of molecular and cellular components. The physiological properties of neural network components can be quantified with high throughput. The ability to assess many animals per study has been critical in relating physiological properties to behavior. By contrast, the synaptic structure of neural circuits is presently quantifiable only with low throughput. This low throughput hampers efforts to understand how variations in network structure relate to variations in behavior. For neuroanatomical reconstruction, there is a methodological gulf between electron microscopic (EM) methods, which yield dense connectomes at considerable expense and low throughput, and light microscopic (LM) methods, which provide molecular and cell-type specificity at high throughput but without synaptic resolution. To bridge this gulf, we developed a high-throughput analysis pipeline and imaging protocol using tissue expansion and light sheet microscopy (ExLLSM) to rapidly reconstruct selected circuits across many animals with single-synapse resolution and molecular contrast. Using Drosophila to validate this approach, we demonstrate that it yields synaptic counts similar to those obtained by EM, enables synaptic connectivity to be compared across sex and experience, and can be used to correlate structural connectivity, functional connectivity, and behavior. This approach fills a critical methodological gap in studying variability in the structure and function of neural circuits across individuals within and between species., Competing Interests: JL, HO, XD, IP, TK, JC, KR, CG, AH, KW, JB, DM, LM, BM, SS, BD No competing interests declared, RG, PT is a co-inventor on multiple patents related to expansion microscopy, EB is a co-inventor on multiple patents related to expansion microscopy and is also a co-founder of a company that aims to pursue commercial deployment of expansion microscopy-related technology, (© 2022, Lillvis et al.)

Published

2022

10. Classification and genetic targeting of cell types in the primary taste and premotor center of the adult Drosophila brain.

Author

Sterne GR, Otsuna H, Dickson BJ, and Scott K

Subjects

Animals, Cell Line, Cluster Analysis, Female, Drosophila melanogaster genetics, Drosophila melanogaster physiology, Motor Cortex cytology, Motor Cortex physiology, Neurons cytology, Neurons physiology, Taste Perception genetics, Taste Perception physiology

Abstract

Neural circuits carry out complex computations that allow animals to evaluate food, select mates, move toward attractive stimuli, and move away from threats. In insects, the subesophageal zone (SEZ) is a brain region that receives gustatory, pheromonal, and mechanosensory inputs and contributes to the control of diverse behaviors, including feeding, grooming, and locomotion. Despite its importance in sensorimotor transformations, the study of SEZ circuits has been hindered by limited knowledge of the underlying diversity of SEZ neurons. Here, we generate a collection of split-GAL4 lines that provides precise genetic targeting of 138 different SEZ cell types in adult Drosophila melanogaster , comprising approximately one third of all SEZ neurons. We characterize the single-cell anatomy of these neurons and find that they cluster by morphology into six supergroups that organize the SEZ into discrete anatomical domains. We find that the majority of local SEZ interneurons are not classically polarized, suggesting rich local processing, whereas SEZ projection neurons tend to be classically polarized, conveying information to a limited number of higher brain regions. This study provides insight into the anatomical organization of the SEZ and generates resources that will facilitate further study of SEZ neurons and their contributions to sensory processing and behavior., Competing Interests: GS, HO, BD, KS none, (© 2021, Sterne et al.)

Published

2021

11. An unbiased template of the Drosophila brain and ventral nerve cord.

Author

Bogovic JA, Otsuna H, Heinrich L, Ito M, Jeter J, Meissner G, Nern A, Colonell J, Malkesman O, Ito K, and Saalfeld S

Subjects

Animals, Brain ultrastructure, Drosophila melanogaster ultrastructure, Female, Image Processing, Computer-Assisted statistics & numerical data, Male, Microscopy, Confocal, Microscopy, Electron, Nerve Tissue ultrastructure, Brain anatomy & histology, Drosophila melanogaster anatomy & histology, Nerve Tissue anatomy & histology, Neurons ultrastructure

Abstract

The fruit fly Drosophila melanogaster is an important model organism for neuroscience with a wide array of genetic tools that enable the mapping of individual neurons and neural subtypes. Brain templates are essential for comparative biological studies because they enable analyzing many individuals in a common reference space. Several central brain templates exist for Drosophila, but every one is either biased, uses sub-optimal tissue preparation, is imaged at low resolution, or does not account for artifacts. No publicly available Drosophila ventral nerve cord template currently exists. In this work, we created high-resolution templates of the Drosophila brain and ventral nerve cord using the best-available technologies for imaging, artifact correction, stitching, and template construction using groupwise registration. We evaluated our central brain template against the four most competitive, publicly available brain templates and demonstrate that ours enables more accurate registration with fewer local deformations in shorter time., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

12. A connectome and analysis of the adult Drosophila central brain.

Author

Scheffer LK, Xu CS, Januszewski M, Lu Z, Takemura SY, Hayworth KJ, Huang GB, Shinomiya K, Maitlin-Shepard J, Berg S, Clements J, Hubbard PM, Katz WT, Umayam L, Zhao T, Ackerman D, Blakely T, Bogovic J, Dolafi T, Kainmueller D, Kawase T, Khairy KA, Leavitt L, Li PH, Lindsey L, Neubarth N, Olbris DJ, Otsuna H, Trautman ET, Ito M, Bates AS, Goldammer J, Wolff T, Svirskas R, Schlegel P, Neace E, Knecht CJ, Alvarado CX, Bailey DA, Ballinger S, Borycz JA, Canino BS, Cheatham N, Cook M, Dreher M, Duclos O, Eubanks B, Fairbanks K, Finley S, Forknall N, Francis A, Hopkins GP, Joyce EM, Kim S, Kirk NA, Kovalyak J, Lauchie SA, Lohff A, Maldonado C, Manley EA, McLin S, Mooney C, Ndama M, Ogundeyi O, Okeoma N, Ordish C, Padilla N, Patrick CM, Paterson T, Phillips EE, Phillips EM, Rampally N, Ribeiro C, Robertson MK, Rymer JT, Ryan SM, Sammons M, Scott AK, Scott AL, Shinomiya A, Smith C, Smith K, Smith NL, Sobeski MA, Suleiman A, Swift J, Takemura S, Talebi I, Tarnogorska D, Tenshaw E, Tokhi T, Walsh JJ, Yang T, Horne JA, Li F, Parekh R, Rivlin PK, Jayaraman V, Costa M, Jefferis GS, Ito K, Saalfeld S, George R, Meinertzhagen IA, Rubin GM, Hess HF, Jain V, and Plaza SM

Subjects

Animals, Brain physiology, Female, Male, Connectome methods, Drosophila melanogaster physiology, Neurons physiology, Synapses physiology

Abstract

The neural circuits responsible for animal behavior remain largely unknown. We summarize new methods and present the circuitry of a large fraction of the brain of the fruit fly Drosophila melanogaster . Improved methods include new procedures to prepare, image, align, segment, find synapses in, and proofread such large data sets. We define cell types, refine computational compartments, and provide an exhaustive atlas of cell examples and types, many of them novel. We provide detailed circuits consisting of neurons and their chemical synapses for most of the central brain. We make the data public and simplify access, reducing the effort needed to answer circuit questions, and provide procedures linking the neurons defined by our analysis with genetic reagents. Biologically, we examine distributions of connection strengths, neural motifs on different scales, electrical consequences of compartmentalization, and evidence that maximizing packing density is an important criterion in the evolution of the fly's brain., Competing Interests: LS, CX, ZL, ST, KH, GH, KS, SB, JC, PH, WK, LU, TZ, DA, JB, TD, DK, TK, KK, NN, DO, HO, ET, MI, AB, JG, TW, RS, PS, EN, CK, CA, DB, SB, JB, BC, NC, MC, MD, OD, BE, KF, SF, NF, AF, GH, EJ, SK, NK, JK, SL, AL, CM, EM, SM, CM, MN, OO, NO, CO, NP, CP, TP, EP, EP, NR, CR, MR, JR, SR, MS, AS, AS, AS, CS, KS, NS, MS, AS, JS, ST, IT, DT, ET, TT, JW, TY, JH, FL, RP, PR, VJ, MC, GJ, KI, SS, RG, IM, GR, HH, SP No competing interests declared, MJ, JM, TB, LL, PL, LL, VJ is an employee of Google., (© 2020, Scheffer et al.)

Published

2020

13. Conservation and divergence of related neuronal lineages in the Drosophila central brain.

Author

Lee YJ, Yang CP, Miyares RL, Huang YF, He Y, Ren Q, Chen HM, Kawase T, Ito M, Otsuna H, Sugino K, Aso Y, Ito K, and Lee T

Subjects

Animals, Brain cytology, Drosophila melanogaster genetics, Larva, Neurons cytology, Brain physiology, Cell Lineage, Drosophila melanogaster cytology, Neural Stem Cells cytology, Neurogenesis

Abstract

Wiring a complex brain requires many neurons with intricate cell specificity, generated by a limited number of neural stem cells. Drosophila central brain lineages are a predetermined series of neurons, born in a specific order. To understand how lineage identity translates to neuron morphology, we mapped 18 Drosophila central brain lineages. While we found large aggregate differences between lineages, we also discovered shared patterns of morphological diversification. Lineage identity plus Notch-mediated sister fate govern primary neuron trajectories, whereas temporal fate diversifies terminal elaborations. Further, morphological neuron types may arise repeatedly, interspersed with other types. Despite the complexity, related lineages produce similar neuron types in comparable temporal patterns. Different stem cells even yield two identical series of dopaminergic neuron types, but with unrelated sister neurons. Together, these phenomena suggest that straightforward rules drive incredible neuronal complexity, and that large changes in morphology can result from relatively simple fating mechanisms., Competing Interests: YL, CY, RM, YH, YH, QR, HC, TK, MI, HO, KS, YA, KI, TL No competing interests declared, (© 2020, Lee et al.)

Published

2020

14. FluoRender: joint freehand segmentation and visualization for many-channel fluorescence data analysis.

Author

Wan Y, Otsuna H, Holman HA, Bagley B, Ito M, Lewis AK, Colasanto M, Kardon G, Ito K, and Hansen C

Subjects

Algorithms, Animals, Batrachoidiformes metabolism, Extremities anatomy & histology, Eye anatomy & histology, Eye pathology, Image Processing, Computer-Assisted, Imaging, Three-Dimensional, Mice, Microscopy, Fluorescence, Zebrafish anatomy & histology, Zebrafish physiology, Software

Abstract

Background: Image segmentation and registration techniques have enabled biologists to place large amounts of volume data from fluorescence microscopy, morphed three-dimensionally, onto a common spatial frame. Existing tools built on volume visualization pipelines for single channel or red-green-blue (RGB) channels have become inadequate for the new challenges of fluorescence microscopy. For a three-dimensional atlas of the insect nervous system, hundreds of volume channels are rendered simultaneously, whereas fluorescence intensity values from each channel need to be preserved for versatile adjustment and analysis. Although several existing tools have incorporated support of multichannel data using various strategies, the lack of a flexible design has made true many-channel visualization and analysis unavailable. The most common practice for many-channel volume data presentation is still converting and rendering pseudosurfaces, which are inaccurate for both qualitative and quantitative evaluations., Results: Here, we present an alternative design strategy that accommodates the visualization and analysis of about 100 volume channels, each of which can be interactively adjusted, selected, and segmented using freehand tools. Our multichannel visualization includes a multilevel streaming pipeline plus a triple-buffer compositing technique. Our method also preserves original fluorescence intensity values on graphics hardware, a crucial feature that allows graphics-processing-unit (GPU)-based processing for interactive data analysis, such as freehand segmentation. We have implemented the design strategies as a thorough restructuring of our original tool, FluoRender., Conclusion: The redesign of FluoRender not only maintains the existing multichannel capabilities for a greatly extended number of volume channels, but also enables new analysis functions for many-channel data from emerging biomedical-imaging techniques.

Published

2017

15. Stem Cell-Intrinsic, Seven-up-Triggered Temporal Factor Gradients Diversify Intermediate Neural Progenitors.

Author

Ren Q, Yang CP, Liu Z, Sugino K, Mok K, He Y, Ito M, Nern A, Otsuna H, and Lee T

Subjects

Animals, Cell Cycle, Cell Lineage, Cell Proliferation, Drosophila melanogaster metabolism, Gene Expression Profiling, Neurogenesis, Neurons cytology, Neurons metabolism, Stem Cell Factor metabolism, DNA-Binding Proteins metabolism, Drosophila Proteins metabolism, Drosophila melanogaster growth & development, Gene Expression Regulation, Developmental, Neural Stem Cells metabolism, RNA-Binding Proteins metabolism, Receptors, Steroid metabolism

Abstract

Building a sizable, complex brain requires both cellular expansion and diversification. One mechanism to achieve these goals is production of multiple transiently amplifying intermediate neural progenitors (INPs) from a single neural stem cell. Like mammalian neural stem cells, Drosophila type II neuroblasts utilize INPs to produce neurons and glia. Within a given lineage, the consecutively born INPs produce morphologically distinct progeny, presumably due to differential inheritance of temporal factors. To uncover the underlying temporal fating mechanisms, we profiled type II neuroblasts' transcriptome across time. Our results reveal opposing temporal gradients of Imp and Syp RNA-binding proteins (descending and ascending, respectively). Maintaining high Imp throughout serial INP production expands the number of neurons and glia with early temporal fate at the expense of cells with late fate. Conversely, precocious upregulation of Syp reduces the number of cells with early fate. Furthermore, we reveal that the transcription factor Seven-up initiates progression of the Imp/Syp gradients. Interestingly, neuroblasts that maintain initial Imp/Syp levels can still yield progeny with a small range of early fates. We therefore propose that the Seven-up-initiated Imp/Syp gradients create coarse temporal windows within type II neuroblasts to pattern INPs, which subsequently undergo fine-tuned subtemporal patterning., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

16. A toolbox to study epidermal cell types in zebrafish.

Author

Eisenhoffer GT, Slattum G, Ruiz OE, Otsuna H, Bryan CD, Lopez J, Wagner DS, Bonkowsky JL, Chien CB, Dorsky RI, and Rosenblatt J

Subjects

Animals, Cell Death drug effects, Cell Division drug effects, Crosses, Genetic, DNA-Binding Proteins metabolism, Enhancer Elements, Genetic genetics, Epidermis drug effects, Epidermis ultrastructure, Epithelial Cells cytology, Epithelial Cells drug effects, Female, Gene Expression Regulation, Developmental drug effects, Imaging, Three-Dimensional, Male, Morpholinos pharmacology, Time Factors, Transcription Factors metabolism, Zebrafish embryology, Zebrafish genetics, Zebrafish Proteins metabolism, Cytological Techniques methods, Epidermal Cells, Zebrafish metabolism

Abstract

Epithelia provide a crucial protective barrier for our organs and are also the sites where the majority of carcinomas form. Most studies on epithelia and carcinomas use cell culture or organisms where high-resolution live imaging is inaccessible without invasive techniques. Here, we introduce the developing zebrafish epidermis as an excellent in vivo model system for studying a living epithelium. We developed tools to fluorescently tag specific epithelial cell types and express genes in a mosaic fashion using five Gal4 lines identified from an enhancer trap screen. When crossed to a variety of UAS effector lines, we can now track, ablate or monitor single cells at sub-cellular resolution. Using photo-cleavable morpholino oligonucleotides that target gal4, we can also express genes in a mosaic fashion at specific times during development. Together, this system provides an excellent in vivo alternative to tissue culture cells, without the intrinsic concerns of culture conditions or transformation, and enables the investigation of distinct cell types within living epithelial tissues., (© 2017. Published by The Company of Biologists Ltd.)

Published

2017

17. The RNA Binding Protein Igf2bp1 Is Required for Zebrafish RGC Axon Outgrowth In Vivo.

Author

Gaynes JA, Otsuna H, Campbell DS, Manfredi JP, Levine EM, and Chien CB

Subjects

Actins physiology, Animals, Gene Knockdown Techniques, Zebrafish growth & development, Zebrafish physiology, Axons physiology, RNA-Binding Proteins physiology, Retinal Ganglion Cells physiology, Zebrafish Proteins physiology

Abstract

Attractive growth cone turning requires Igf2bp1-dependent local translation of β-actin mRNA in response to external cues in vitro. While in vivo studies have shown that Igf2bp1 is required for cell migration and axon terminal branching, a requirement for Igf2bp1 function during axon outgrowth has not been demonstrated. Using a timelapse assay in the zebrafish retinotectal system, we demonstrate that the β-actin 3'UTR is sufficient to target local translation of the photoconvertible fluorescent protein Kaede in growth cones of pathfinding retinal ganglion cells (RGCs) in vivo. Igf2bp1 knockdown reduced RGC axonal outgrowth and tectal coverage and retinal cell survival. RGC-specific expression of a phosphomimetic Igf2bp1 reduced the density of axonal projections in the optic tract while sparing RGCs, demonstrating for the first time that Igf2bp1 is required during axon outgrowth in vivo. Therefore, regulation of local translation mediated by Igf2bp proteins may be required at all stages of axon development.

Published

2015

18. Parallel neural pathways in higher visual centers of the Drosophila brain that mediate wavelength-specific behavior.

Author

Otsuna H, Shinomiya K, and Ito K

Subjects

Animals, Behavior, Animal physiology, Brain metabolism, Drosophila Proteins metabolism, Neurons metabolism, Photic Stimulation, Transcription Factors metabolism, Visual Pathways metabolism, Brain physiology, Drosophila physiology, Neurons physiology, Visual Pathways physiology, Visual Perception physiology

Abstract

Compared with connections between the retinae and primary visual centers, relatively less is known in both mammals and insects about the functional segregation of neural pathways connecting primary and higher centers of the visual processing cascade. Here, using the Drosophila visual system as a model, we demonstrate two levels of parallel computation in the pathways that connect primary visual centers of the optic lobe to computational circuits embedded within deeper centers in the central brain. We show that a seemingly simple achromatic behavior, namely phototaxis, is under the control of several independent pathways, each of which is responsible for navigation towards unique wavelengths. Silencing just one pathway is enough to disturb phototaxis towards one characteristic monochromatic source, whereas phototactic behavior towards white light is not affected. The response spectrum of each demonstrable pathway is different from that of individual photoreceptors, suggesting subtractive computations. A choice assay between two colors showed that these pathways are responsible for navigation towards, but not for the detection itself of, the monochromatic light. The present study provides novel insights about how visual information is separated and processed in parallel to achieve robust control of an innate behavior.

Published

2014

19. Wnt signaling regulates postembryonic hypothalamic progenitor differentiation.

Author

Wang X, Kopinke D, Lin J, McPherson AD, Duncan RN, Otsuna H, Moro E, Hoshijima K, Grunwald DJ, Argenton F, Chien CB, Murtaugh LC, and Dorsky RI

Subjects

Animals, Hypothalamus metabolism, Mice, Neuroglia cytology, Neuroglia metabolism, Stem Cells metabolism, Zebrafish embryology, Hypothalamus cytology, Neurogenesis, Stem Cells cytology, Wnt Proteins metabolism, Wnt Signaling Pathway, Zebrafish growth & development

Abstract

Previous studies have raised the possibility that Wnt signaling may regulate both neural progenitor maintenance and neuronal differentiation within a single population. Here we investigate the role of Wnt/β-catenin activity in the zebrafish hypothalamus and find that the pathway is first required for the proliferation of unspecified hypothalamic progenitors in the embryo. At later stages, including adulthood, sequential activation and inhibition of Wnt activity is required for the differentiation of neural progenitors and negatively regulates radial glia differentiation. The presence of Wnt activity is conserved in hypothalamic progenitors of the adult mouse, where it plays a conserved role in inhibiting the differentiation of radial glia. This study establishes the vertebrate hypothalamus as a model for Wnt-regulated postembryonic neural progenitor differentiation and defines specific roles for Wnt signaling in neurogenesis., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

20. Crowding induces live cell extrusion to maintain homeostatic cell numbers in epithelia.

Author

Eisenhoffer GT, Loftus PD, Yoshigi M, Otsuna H, Chien CB, Morcos PA, and Rosenblatt J

Subjects

Animal Fins anatomy & histology, Animal Fins cytology, Animal Fins embryology, Animals, Apoptosis, Cell Count, Cell Death, Cell Line, Cell Movement, Cell Proliferation, Cell Survival, Colon cytology, Dogs, Embryo, Nonmammalian cytology, Embryo, Nonmammalian embryology, Epidermal Cells, Epidermis embryology, Humans, Ion Channels deficiency, Ion Channels genetics, Ion Channels metabolism, Lysophospholipids metabolism, Models, Biological, Neoplasms pathology, Sphingosine analogs & derivatives, Sphingosine metabolism, Zebrafish anatomy & histology, Zebrafish embryology, Zebrafish Proteins deficiency, Zebrafish Proteins genetics, Zebrafish Proteins metabolism, Epithelial Cells cytology, Homeostasis

Abstract

For an epithelium to provide a protective barrier, it must maintain homeostatic cell numbers by matching the number of dividing cells with the number of dying cells. Although compensatory cell division can be triggered by dying cells, it is unknown how cell death might relieve overcrowding due to proliferation. When we trigger apoptosis in epithelia, dying cells are extruded to preserve a functional barrier. Extrusion occurs by cells destined to die signalling to surrounding epithelial cells to contract an actomyosin ring that squeezes the dying cell out. However, it is not clear what drives cell death during normal homeostasis. Here we show in human, canine and zebrafish cells that overcrowding due to proliferation and migration induces extrusion of live cells to control epithelial cell numbers. Extrusion of live cells occurs at sites where the highest crowding occurs in vivo and can be induced by experimentally overcrowding monolayers in vitro. Like apoptotic cell extrusion, live cell extrusion resulting from overcrowding also requires sphingosine 1-phosphate signalling and Rho-kinase-dependent myosin contraction, but is distinguished by signalling through stretch-activated channels. Moreover, disruption of a stretch-activated channel, Piezo1, in zebrafish prevents extrusion and leads to the formation of epithelial cell masses. Our findings reveal that during homeostatic turnover, growth and division of epithelial cells on a confined substratum cause overcrowding that leads to their extrusion and consequent death owing to the loss of survival factors. These results suggest that live cell extrusion could be a tumour-suppressive mechanism that prevents the accumulation of excess epithelial cells.

Published

2012

21. A complex choreography of cell movements shapes the vertebrate eye.

Author

Kwan KM, Otsuna H, Kidokoro H, Carney KR, Saijoh Y, and Chien CB

Subjects

Analysis of Variance, Animals, Cell Cycle physiology, Chick Embryo, Image Processing, Computer-Assisted, Imaging, Three-Dimensional, Lens, Crystalline physiology, Retina cytology, Retina physiology, Retinal Pigment Epithelium cytology, Retinal Pigment Epithelium physiology, Time Factors, Cell Movement physiology, Eye embryology, Morphogenesis physiology, Signal Transduction physiology, Zebrafish embryology

Abstract

Optic cup morphogenesis (OCM) generates the basic structure of the vertebrate eye. Although it is commonly depicted as a series of epithelial sheet folding events, this does not represent an empirically supported model. Here, we combine four-dimensional imaging with custom cell tracking software and photoactivatable fluorophore labeling to determine the cellular dynamics underlying OCM in zebrafish. Although cell division contributes to growth, we find it dispensable for eye formation. OCM depends instead on a complex set of cell movements coordinated between the prospective neural retina, retinal pigmented epithelium (RPE) and lens. Optic vesicle evagination persists for longer than expected; cells move in a pinwheel pattern during optic vesicle elongation and retinal precursors involute around the rim of the invaginating optic cup. We identify unanticipated movements, particularly of central and peripheral retina, RPE and lens. From cell tracking data, we generate retina, RPE and lens subdomain fate maps, which reveal novel adjacencies that might determine corresponding developmental signaling events. Finally, we find that similar movements also occur during chick eye morphogenesis, suggesting that the underlying choreography is conserved among vertebrates.

Published

2012

22. Synaptic activity and activity-dependent competition regulates axon arbor maturation, growth arrest, and territory in the retinotectal projection.

Author

Ben Fredj N, Hammond S, Otsuna H, Chien CB, Burrone J, and Meyer MP

Subjects

Analysis of Variance, Animals, Animals, Genetically Modified, Calcium metabolism, Cells, Cultured, DNA-Binding Proteins genetics, Dizocilpine Maleate pharmacology, Embryo, Mammalian, Embryo, Nonmammalian, Excitatory Amino Acid Antagonists pharmacology, Gene Expression Regulation, Developmental drug effects, Gene Expression Regulation, Developmental genetics, Green Fluorescent Proteins genetics, Growth Cones physiology, Hippocampus cytology, Metalloendopeptidases genetics, Nystagmus, Optokinetic drug effects, Nystagmus, Optokinetic physiology, Pseudopodia physiology, Pyridinium Compounds, Quaternary Ammonium Compounds, Rats, Rats, Sprague-Dawley, Retina cytology, Retina drug effects, Superior Colliculi cytology, Superior Colliculi drug effects, Synaptophysin metabolism, Tetanus Toxin genetics, Time Factors, Transcription Factors genetics, Transfection methods, Visual Pathways drug effects, Visual Pathways physiology, Zebrafish, Zebrafish Proteins genetics, Axons physiology, Neurons physiology, Retina physiology, Superior Colliculi physiology, Synapses physiology

Abstract

In the retinotectal projection, synapses guide retinal ganglion cell (RGC) axon arbor growth by promoting branch formation and by selectively stabilizing branches. To ask whether presynaptic function is required for this dual role of synapses, we have suppressed presynaptic function in single RGCs using targeted expression of tetanus toxin light-chain fused to enhanced green fluorescent protein (TeNT-Lc:EGFP). Time-lapse imaging of singly silenced axons as they arborize in the tectum of zebrafish larvae shows that presynaptic function is not required for stabilizing branches or for generating an arbor of appropriate complexity. However, synaptic activity does regulate two distinct aspects of arbor development. First, single silenced axons fail to arrest formation of highly dynamic but short-lived filopodia that are a feature of immature axons. Second, single silenced axons fail to arrest growth of established branches and so occupy significantly larger territories in the tectum than active axons. However, if activity-suppressed axons had neighbors that were also silent, axonal arbors appeared normal in size. A similar reversal in phenotype was observed when single TeNT-Lc:EGFP axons are grown in the presence of the NMDA receptor antagonist MK801 [(+)-5-methyl-10,11- dihydro-5H-dibenzo[a,d]cyclohepten-5,10-imine maleate]. Although expansion of arbor territory is prevented when neighbors are silent, formation of transient filopodia is not. These results suggest that synaptic activity by itself regulates filopodia formation regardless of activity in neighboring cells but that the ability to arrest growth and focusing of axonal arbors in the target is an activity-dependent, competitive process.

Published

2010

23. 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