Your search keyword '"Gaia Tavosanis"' showing total 14 results

1. The branching code: A model of actin-driven dendrite arborization

Author

Tomke Stürner, André Ferreira Castro, Maren Philipps, Hermann Cuntz, and Gaia Tavosanis

Subjects

computational modeling, Molecular biology [CP], Neuronal Plasticity, metabolism [Actins], morphometrics, Neuroscience [CP], metabolism [Drosophila Proteins], time-lapse imaging, Dendrites, optimal wiring, metabolism [Drosophila], General Biochemistry, Genetics and Molecular Biology, neuron, Actins, dendrite, dendritic arborization neurons, Animals, Drosophila Proteins, metabolism [Dendrites], Drosophila, ddc:610, actin-modulatory proteins, actin

Abstract

Summary The cytoskeleton is crucial for defining neuronal-type-specific dendrite morphologies. To explore how the complex interplay of actin-modulatory proteins (AMPs) can define neuronal types in vivo, we focused on the class III dendritic arborization (c3da) neuron of Drosophila larvae. Using computational modeling, we reveal that the main branches (MBs) of c3da neurons follow general models based on optimal wiring principles, while the actin-enriched short terminal branches (STBs) require an additional growth program. To clarify the cellular mechanisms that define this second step, we thus concentrated on STBs for an in-depth quantitative description of dendrite morphology and dynamics. Applying these methods systematically to mutants of six known and novel AMPs, we revealed the complementary roles of these individual AMPs in defining STB properties. Our data suggest that diverse dendrite arbors result from a combination of optimal-wiring-related growth and individualized growth programs that are neuron-type specific.

Published

2022

2. A Quantitative Model of Sporadic Axonal Degeneration in the

Author

Mélisande, Richard, Karolína, Doubková, Yohei, Nitta, Hiroki, Kawai, Atsushi, Sugie, and Gaia, Tavosanis

Subjects

Synapses, Animals, Drosophila Proteins, Drosophila, Female, Neurodegenerative Diseases, Axons

Abstract

In human neurodegenerative diseases, neurons undergo axonal degeneration months to years before they die. Here, we developed a system modeling early degenerative events in

Published

2021

3. Achieving functional neuronal dendrite structure through sequential stochastic growth and retraction

Author

Gaia Tavosanis, Amirhoushang Bahrami, Tomke Stürner, Lothar Baltruschat, Peter Jedlicka, Hermann Cuntz, André Ferreira Castro, Ferreira Castro, André [0000-0002-6841-1952], Stürner, Tomke [0000-0003-4054-0784], Bahrami, Amirhoushang [0000-0001-5841-2516], Jedlicka, Peter [0000-0001-6571-5742], Tavosanis, Gaia [0000-0002-8679-5515], Cuntz, Hermann [0000-0001-5445-0507], and Apollo - University of Cambridge Repository

Subjects

dendrite retraction, Sensory Receptor Cells, QH301-705.5, Science, self-organisation, Green Fluorescent Proteins, Morphogenesis, metabolism [Drosophila Proteins], Sensory system, Crawling, Dendritic branch, Biology, General Biochemistry, Genetics and Molecular Biology, neuroscience, Animals, Genetically Modified, developmental biology, Dendrite (crystal), dendrite growth, physiology [Gene Expression Regulation, Developmental], genetics [Green Fluorescent Proteins], Animals, Drosophila Proteins, Biology (General), Mechanotransduction, mechanotransduction, D. melanogaster, General Immunology and Microbiology, General Neuroscience, fungi, Gene Expression Regulation, Developmental, physiology [Dendrites], Dendrites, General Medicine, physiology [Morphogenesis], Membrane curvature, Medicine, Drosophila, computer model, physiology [Sensory Receptor Cells], ddc:600, physiology [Drosophila], Neuroscience, Developmental biology, dendrite function, Research Article

Abstract

Class I ventral posterior dendritic arborisation (c1vpda) proprioceptive sensory neurons respond to contractions in theDrosophilalarval body wall during crawling. Their dendritic branches run along the direction of contraction, possibly a functional requirement to maximise membrane curvature during crawling contractions. Although the molecular machinery of dendritic patterning in c1vpda has been extensively studied, the process leading to the precise elaboration of their comb-like shapes remains elusive. Here, to link dendrite shape with its proprioceptive role, we performed long-term, non-invasive,in vivotime-lapse imaging of c1vpda embryonic and larval morphogenesis to reveal a sequence of differentiation stages. We combined computer models and dendritic branch dynamics tracking to propose that distinct sequential phases of targeted growth and stochastic retraction achieve efficient dendritic trees both in terms of wire and function. Our study shows how dendrite growth balances structure–function requirements, shedding new light on general principles of self-organisation in functionally specialised dendrites.In briefAn optimal wire and function trade-off emerges from noisy growth and stochastic retraction duringDrosophilaclass I ventral posterior dendritic arborisation (c1vpda) dendrite development.HighlightsC1vpda dendrite outgrowth follows wire constraints.Stochastic retraction of functionally suboptimal branches in a subsequent growth phase.C1vpda growth rules favour branches running parallel to larval body wall contraction.Comprehensive growth model reproduces c1vpda developmentin silico.

Published

2020

4. Modulators of hormonal response regulate temporal fate specification in the Drosophila brain

Author

Giovanni Marchetti and Gaia Tavosanis

Subjects

Cancer Research, Receptors, Steroid, growth & development [Drosophila], QH426-470, metabolism [Drosophila], Biochemistry, chemistry.chemical_compound, 0302 clinical medicine, RNA interference, Cell Signaling, Transforming Growth Factor beta, Animal Cells, Drosophila Proteins, Membrane Receptor Signaling, Genetics (clinical), Zinc finger transcription factor, Neurons, Staining, Motor Neurons, 0303 health sciences, metabolism [Transforming Growth Factor beta], growth & development [Brain], Brain, Gene Expression Regulation, Developmental, Cell Staining, Hormone Receptor Signaling, Cell biology, Nucleic acids, medicine.anatomical_structure, metabolism [Mushroom Bodies], Genetic interference, Mushroom bodies, metabolism [Ecdysone], Drosophila, Epigenetics, Signal transduction, Cellular Types, Ecdysone, Signal Transduction, Research Article, metabolism [Kruppel-Like Transcription Factors], Kruppel-Like Transcription Factors, metabolism [Drosophila Proteins], Biology, Research and Analysis Methods, 03 medical and health sciences, Neuroblast, Neuroblasts, medicine, Genetics, Animals, ddc:610, Molecular Biology Techniques, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Mushroom Bodies, 030304 developmental biology, Progenitor, Body Patterning, growth & development [Mushroom Bodies], Metamorphosis, Biology and Life Sciences, metabolism [Receptors, Steroid], Cell Biology, chemistry, nervous system, metabolism [Brain], Specimen Preparation and Treatment, Cellular Neuroscience, RNA, Neuron, Gene expression, Ecdysone receptor, 030217 neurology & neurosurgery, Neuroscience, Cloning, Developmental Biology

Abstract

Neuronal diversity is at the core of the complex processing operated by the nervous system supporting fundamental functions such as sensory perception, motor control or memory formation. A small number of progenitors guarantee the production of this neuronal diversity, with each progenitor giving origin to different neuronal types over time. How a progenitor sequentially produces neurons of different fates and the impact of extrinsic signals conveying information about developmental progress or environmental conditions on this process represent key, but elusive questions. Each of the four progenitors of the Drosophila mushroom body (MB) sequentially gives rise to the MB neuron subtypes. The temporal fate determination pattern of MB neurons can be influenced by extrinsic cues, conveyed by the steroid hormone ecdysone. Here, we show that the activation of Transforming Growth Factor-β (TGF-β) signalling via glial-derived Myoglianin regulates the fate transition between the early-born α’β’ and the pioneer αβ MB neurons by promoting the expression of the ecdysone receptor B1 isoform (EcR-B1). While TGF-β signalling is required in MB neuronal progenitors to promote the expression of EcR-B1, ecdysone signalling acts postmitotically to consolidate theα’β’ MB fate. Indeed, we propose that if these signalling cascades are impaired α’β’ neurons lose their fate and convert to pioneer αβ. Conversely, an intrinsic signal conducted by the zinc finger transcription factor Krüppel-homolog 1 (Kr-h1) antagonises TGF-β signalling and acts as negative regulator of the response mediated by ecdysone in promoting α’β’ MB neuron fate consolidation. Taken together, the consolidation of α’β’ MB neuron fate requires the response of progenitors to local signalling to enable postmitotic neurons to sense a systemic signal., Author summary Throughout the development of the central nervous system (CNS), a vast number of neuronal types are produced with striking precision. The unique identity of each neuronal cell type and the great cellular complexity in the CNS are established by intricate gene regulatory networks. Disruption of these identity programs leads to neurodevelopmental disorders and defects in cognition. Here, we report an important regulatory mechanism involved in consolidating neuronal fate. We show that during brain development local signalling, derived from interactions between glial cells and neuronal progenitors, is required to promote the expression of a hormone receptor in immature neurons. The perception of a systemic hormonal cue in those postmitotic neurons is fundamental for the consolidation of their neuronal fate. In this context, we additionally uncover an intrinsic regulatory mechanism that coordinates the hormone response to maintain the final neuronal fate.

Published

2019

5. Analyzing Synaptic Modulation of Drosophila melanogaster Photoreceptors after Exposure to Prolonged Light

Author

Atsushi, Sugie, Christoph, Möhl, Satoko, Hakeda-Suzuki, Hideaki, Matsui, Takashi, Suzuki, and Gaia, Tavosanis

Subjects

Luminescent Agents, Light, metabolism [Luminescent Agents], Green Fluorescent Proteins, Presynaptic Terminals, metabolism [Drosophila Proteins], metabolism [Synapses], Synaptic Transmission, metabolism [Photoreceptor Cells, Invertebrate], Protein Transport, Drosophila melanogaster, physiology [Synaptic Transmission], ddc:570, metabolism [Green Fluorescent Proteins], Synapses, metabolism [Drosophila melanogaster], Animals, radiation effects [Photoreceptor Cells, Invertebrate], Drosophila Proteins, Photoreceptor Cells, Invertebrate, Neuroscience, Protein Binding

Abstract

The nervous system has the remarkable ability to adapt and respond to various stimuli. This neural adjustment is largely achieved through plasticity at the synaptic level. The Active Zone (AZ) is the region at the presynaptic membrane that mediates neurotransmitter release and is composed of a dense collection of scaffold proteins. AZs of Drosophila melanogaster (Drosophila) photoreceptors undergo molecular remodeling after prolonged exposure to natural ambient light. Thus the level of neuronal activity can rearrange the molecular composition of the AZ and contribute to the regulation of the functional output. Starting from the light exposure set-up preparation to the immunohistochemistry, this protocol details how to quantify the number, the spatial distribution, and the delocalization level of synaptic molecules at AZs in Drosophila photoreceptors. Using image analysis software, clusters of the GFP-fused AZ component Bruchpilot were identified for each R8 photoreceptor (R8) axon terminal. Detected Bruchpilot spots were automatically assigned to individual R8 axons. To calculate the distribution of spot frequency along the axon, we implemented a customized software plugin. Each axon's start-point and end-point were manually defined and the position of each Bruchpilot spot was projected onto the connecting line between start and end-point. Besides the number of Bruchpilot clusters, we also quantified the delocalization level of Bruchpilot-GFP within the clusters. These measurements reflect in detail the spatially resolved synaptic dynamics in a single neuron under different environmental conditions to stimuli.

Published

2017

6. The gap junction protein Innexin3 is required for eye disc growth in Drosophila

Author

Michael Hoch, Reinhard Bauer, Gaia Tavosanis, and Mélisande Richard

Subjects

0301 basic medicine, metabolism [Epithelium], genetic structures, Optic Disk, Optic disk, metabolism [Drosophila Proteins], Innexin, growth & development [Optic Disk], INX3 protein, Drosophila, Biology, metabolism [Larva], metabolism [Optic Disk], Epithelium, Connexins, 03 medical and health sciences, anatomy & histology [Optic Disk], ddc:570, metabolism [Drosophila melanogaster], Animals, Drosophila Proteins, Molecular Biology, Cell Proliferation, Cell growth, Cell Biology, Compound eye, Anatomy, Organ Size, metabolism [Connexins], biology.organism_classification, eye diseases, Cell biology, 030104 developmental biology, Drosophila melanogaster, Phenotype, Larva, Eye development, sense organs, Signal transduction, growth & development [Drosophila melanogaster], Drosophila Protein, Developmental Biology, Signal Transduction

Abstract

The Drosophila compound eye develops from a bilayered epithelial sac composed of an upper peripodial epithelium layer and a lower disc proper, the latter giving rise to the eye itself. During larval stages, complex signalling events between the layers contribute to the control of cell proliferation and differentiation in the disc. Previous work in our lab established the gap junction protein Innexin2 (Inx2) as crucial for early larval eye disc growth. By analysing the contribution of other Innexins to eye size control, we have identified Innexin3 (Inx3) as an important growth regulator. Depleting inx3 during larval eye development reduces eye size, while elevating inx3 levels increases eye size, thus phenocopying the inx2 loss- and gain-of-function situation. As demonstrated previously for inx2, inx3 regulates disc cell proliferation and interacts genetically with the Dpp pathway, being required for the proper activation of the Dpp pathway transducer Mad at the furrow and the expression of Dpp receptor Punt in the eye disc. At the developmental timepoint corresponding to eye disc growth, Inx3 colocalises with Inx2 in disc proper and peripodial epithelium cell membranes. In addition, we show that Inx3 protein levels critically depend on inx2 throughout eye development and that inx3 modulates Inx2 protein levels in the larval eye disc. Rescue experiments demonstrate that Inx3 and Inx2 cooperate functionally to enable eye disc growth in Drosophila. Finally, we demonstrate that expression of Inx3 and Inx2 is not only needed in the disc proper but also in the peripodial epithelium to regulate growth of the eye disc. Our data provide a functional demonstration that putative Inx2/Inx3 heteromeric channels regulate organ size.

Published

2017

7. Rotating for elongation: Fat2 whips for the race

Author

Gaia Tavosanis and Tomke Stürner

Subjects

0301 basic medicine, Cell, Morphogenesis, metabolism [Multiprotein Complexes], Motility, Reviews, metabolism [Drosophila Proteins], 03 medical and health sciences, cytology [Drosophila melanogaster], Cell Movement, ddc:570, metabolism [Drosophila melanogaster], medicine, Animals, Drosophila Proteins, Cytoskeleton, Actin, biology, Cadherin, Comment, metabolism [Cadherins], Cell Biology, biology.organism_classification, Actin cytoskeleton, Cadherins, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Multiprotein Complexes, Drosophila melanogaster

Abstract

Dynamic rearrangements of the actin cytoskeleton are crucial for cell shape and migration. In this issue, Squarr et al. (2016. J. Cell Biol. http://dx.doi.org/10.1083/jcb.201508081) show that the cadherin superfamily protein Fat2 regulates actin-rich protrusions driving collective cell migration during Drosophila melanogaster egg morphogenesis through its interaction with the WAVE regulatory complex.

Published

2016

8. Fascin controls neuronal class-specific dendrite arbor morphology

Author

Yun Zhang, Adrian W. Moore, Julia Nagel, Gaia Tavosanis, Caroline Delandre, and Friedrich Forstner

Subjects

Nerve net, Genes, Insect, genetics [Carrier Proteins], Animals, Genetically Modified, genetics [Drosophila Proteins], metabolism [Homeodomain Proteins], metabolism [Drosophila melanogaster], ultrastructure [Dendrites], Drosophila Proteins, metabolism [Transcription Factors], Phosphorylation, metabolism [Nerve Net], growth & development [Larva], genetics [Drosophila melanogaster], Microfilament Proteins, Neurogenesis, classification [Sensory Receptor Cells], Nuclear Proteins, genetics [Nuclear Proteins], Cell migration, chemistry [Carrier Proteins], physiology [Neurogenesis], genetics [Transcription Factors], growth & development [Nerve Net], Cell biology, Drosophila melanogaster, medicine.anatomical_structure, genetics [Neurogenesis], Larva, chemistry [Drosophila Proteins], metabolism [Nuclear Proteins], Sensory Receptor Cells, genetics [Homeodomain Proteins], metabolism [Drosophila Proteins], Dendrite, Sensory system, macromolecular substances, metabolism [Larva], fascin, Biology, ddc:570, medicine, metabolism [Sensory Receptor Cells], Animals, metabolism [Dendrites], chemistry [Microfilament Proteins], Molecular Biology, Transcription factor, Fascin, Homeodomain Proteins, ct protein, Drosophila, metabolism [Microfilament Proteins], Dendrites, nervous system, biology.protein, growth & development [Drosophila melanogaster], genetics [Microfilament Proteins], Nerve Net, Carrier Proteins, metabolism [Carrier Proteins], ultrastructure [Sensory Receptor Cells], Transcription Factors, Developmental Biology

Abstract

The branched morphology of dendrites represents a functional hallmark of distinct neuronal types. Nonetheless, how diverse neuronal class-specific dendrite branches are generated is not understood. We investigated specific classes of sensory neurons of Drosophila larvae to address the fundamental mechanisms underlying the formation of distinct branch types. We addressed the function of fascin, a conserved actin-bundling protein involved in filopodium formation, in class III and class IV sensory neurons. We found that the terminal branchlets of different classes of neurons have distinctive dynamics and are formed on the basis of molecularly separable mechanisms; in particular, class III neurons require fascin for terminal branching whereas class IV neurons do not. In class III neurons, fascin controls the formation and dynamics of terminal branchlets. Previous studies have shown that transcription factor combinations define dendrite patterns; we find that fascin represents a downstream component of such programs, as it is a major effector of the transcription factor Cut in defining class III-specific dendrite morphology. Furthermore, fascin defines the morphological distinction between class III and class IV neurons. In fact, loss of fascin function leads to a partial conversion of class III neurons to class IV characteristics, while the reverse effect is obtained by fascin overexpression in class IV neurons. We propose that dedicated molecular mechanisms underlie the formation and dynamics of distinct dendrite branch types to elicit the accurate establishment of neuronal circuits.

Published

2012

9. Structural Long-Term Changes at Mushroom Body Input Synapses

Author

Florian Leiss, Peter Kloppenburg, Gaia Tavosanis, Till F. M. Andlauer, Stephan J. Sigrist, Frauke Christiansen, Friedrich Forstner, Moritz Paehler, Stephan Knapek, and Malte C. Kremer

Subjects

Potassium Channels, Recombinant Fusion Proteins, Action Potentials, Sensory system, Cellular level, Neurotransmission, Biology, Synaptic Transmission, General Biochemistry, Genetics and Molecular Biology, Calyx, Postsynaptic potential, Animals, Drosophila Proteins, Active zone, Mushroom Bodies, Neurons, Agricultural and Biological Sciences(all), Biochemistry, Genetics and Molecular Biology(all), fungi, Anatomy, Smell, Brain region, nervous system, Synapses, Mushroom bodies, Drosophila, General Agricultural and Biological Sciences, Neuroscience

Abstract

SummaryHow does the sensory environment shape circuit organization in higher brain centers? Here we have addressed the dependence on activity of a defined circuit within the mushroom body of adult Drosophila. This is a brain region receiving olfactory information and involved in long-term associative memory formation [1]. The main mushroom body input region, named the calyx, undergoes volumetric changes correlated with alterations of experience [2–5]. However, the underlying modifications at the cellular level remained unclear. Within the calyx, the clawed dendritic endings of mushroom body Kenyon cells form microglomeruli, distinct synaptic complexes with the presynaptic boutons of olfactory projection neurons [6, 7]. We developed tools for high-resolution imaging of pre- and postsynaptic compartments of defined calycal microglomeruli. Here we show that preventing firing of action potentials or synaptic transmission in a small, identified fraction of projection neurons causes alterations in the size, number, and active zone density of the microglomeruli formed by these neurons. These data provide clear evidence for activity-dependent organization of a circuit within the adult brain of the fly.

Published

2010

10. Synaptic organization in the adultDrosophilamushroom body calyx

Author

Ian A. Meinertzhagen, Nancy J. Butcher, Gaia Tavosanis, Claudia Groh, and Florian Leiss

Subjects

Models, Anatomic, Olfactory system, Kenyon cell, Presynaptic Terminals, Dendrite, Biology, Filamentous actin, Calyx, Neural Pathways, medicine, Animals, Drosophila Proteins, Mushroom Bodies, Neurons, Microscopy, Confocal, Glutamate Decarboxylase, General Neuroscience, fungi, Dendrites, Immunohistochemistry, Actins, Associative learning, Microscopy, Electron, medicine.anatomical_structure, nervous system, Synapses, Mushroom bodies, Drosophila, Antennal lobe, Neuroscience

Abstract

Insect mushroom bodies are critical for olfactory associative learning. We have carried out an extensive quantitative description of the synaptic organization of the calyx of adult Drosophila melanogaster, the main olfactory input region of the mushroom body. By using high-resolution confocal microscopy, electron microscopy-based three-dimensional reconstructions, and genetic labeling of the neuronal populations contributing to the calyx, we resolved the precise connections between large cholinergic boutons of antennal lobe projection neurons and the dendrites of Kenyon cells, the mushroom body intrinsic neurons. Throughout the calyx, these elements constitute synaptic complexes called microglomeruli. By single-cell labeling, we show that each Kenyon cell's claw-like dendritic specialization is highly enriched in filamentous actin, suggesting that this might be a site of plastic reorganization. In fact, Lim kinase (LimK) overexpression in the Kenyon cells modifies the shape of the microglomeruli. Confocal and electron microscopy indicate that each Kenyon cell claw enwraps a single bouton of a projection neuron. Each bouton is contacted by a number of such claw-like specializations as well as profiles of gamma-aminobutyric acid-positive neurons. The dendrites of distinct populations of Kenyon cells involved in different types of memory are partially segregated within the calyx and contribute to different subsets of microglomeruli. Our analysis suggests, though, that projection neuron boutons can contact more than one type of Kenyon cell. These findings represent an important basis for the functional analysis of the olfactory pathway, including the formation of associative olfactory memories.

Published

2009

11. Slit and Robo regulate dendrite branching and elongation of space-filling neurons in Drosophila

Author

André Reissaus, Gaia Tavosanis, and Svetla Dimitrova

Subjects

Embryo, Nonmammalian, Mutant, PNS, Nerve Tissue Proteins, Dendrite, Robo, Biology, Branching (polymer chemistry), Slit, Peripheral Nervous System, medicine, Animals, Drosophila Proteins, Receptors, Immunologic, Molecular Biology, Process (anatomy), Neurons, Cell Differentiation, Dendrites, Cell Biology, Anatomy, Embryonic stem cell, Cell biology, Drosophila melanogaster, medicine.anatomical_structure, nervous system, Receptive field, Larva, Mutation, Drosophila, Elongation, Developmental Biology

Abstract

Space-filling neurons extensively sample their receptive fields with fine dendritic branches. In this study we show that a member of the conserved Robo receptor family, Robo, and its ligand Slit regulate the dendritic differentiation of space-filling neurons. Loss of Robo or Slit function leads to faster elongating and less branched dendrites of the complex and space-filling class IV multi-dendritic dendrite-arborization (md-da) neurons in the Drosophila embryonic peripheral nervous system, but not of the simpler class I neurons. The total dendrite length of Class IV neurons is not modified in robo or slit mutant embryos. Robo mediates this process cell-autonomously. Upon Robo over-expression in md-da neurons the dendritic tree is simplified and time-lapse analysis during larval stages indicates that this is due to reduction in the number of newly formed branches. We propose that Slit, through Robo, provides an extrinsic signal to coordinate the growth rate and the branching level of space-filling neurons, thus allowing them to appropriately cover their target field.

Published

2008

12. Steroid Hormone Ecdysone Signaling Specifies Mushroom Body Neuron Sequential Fate via Chinmo

Author

Giovanni Marchetti and Gaia Tavosanis

Subjects

0301 basic medicine, Receptors, Steroid, Kenyon cell, medicine.medical_treatment, Regulator, ecdysone receptor, genetics [Larva], chemistry.chemical_compound, genetics [Drosophila Proteins], genetics [Receptors, Steroid], metabolism [Drosophila melanogaster], growth & development [Pupa], Drosophila Proteins, genetics [Nerve Tissue Proteins], growth & development [Larva], Neurons, genetics [Drosophila melanogaster], metabolism [Pupa], Pupa, Gene Expression Regulation, Developmental, Cell Differentiation, physiology [Neurons], Cell biology, Drosophila melanogaster, medicine.anatomical_structure, Larva, Mushroom bodies, metabolism [Ecdysone], General Agricultural and Biological Sciences, Ecdysone, Signal Transduction, medicine.medical_specialty, metabolism [Drosophila Proteins], Nerve Tissue Proteins, metabolism [Larva], Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, ddc:570, Internal medicine, medicine, Animals, Transcription factor, Mushroom Bodies, growth & development [Mushroom Bodies], genetics [Pupa], metabolism [Nerve Tissue Proteins], metabolism [Receptors, Steroid], Chinmo protein, Drosophila, Steroid hormone, 030104 developmental biology, Endocrinology, chemistry, Neuron, growth & development [Drosophila melanogaster], Ecdysone receptor

Abstract

The functional variety in neuronal composition of an adult brain is established during development. Recent studies proposed that interactions between genetic intrinsic programs and external cues are necessary to generate proper neural diversity [1]. However, the molecular mechanisms underlying this developmental process are still poorly understood. Three main subtypes of Drosophila mushroom body (MB) neurons are sequentially generated during development and provide a good example of developmental neural plasticity [2]. Our present data propose that the environmentally controlled steroid hormone ecdysone functions as a regulator of early-born MB neuron fate during larval-pupal transition. We found that the BTB-zinc finger factor Chinmo acts upstream of ecdysone signaling to promote a neuronal fate switch. Indeed, Chinmo regulates the expression of the ecdysone receptor B1 isoform to mediate the production of γ and α'β' MB neurons. In addition, we provide genetic evidence for a regulatory negative feedback loop driving the α'β' to αβ MB neuron transition in which ecdysone signaling in turn controls microRNA let-7 depression of Chinmo expression. Thus, our results uncover a novel interaction in the MB neural specification pathway for temporal control of neuronal identity by interplay between an extrinsic hormonal signal and an intrinsic transcription factor cascade.

Published

2017

13. The Drosophila Myosin VI Jaguar Is Required for Basal Protein Targeting and Correct Spindle Orientation in Mitotic Neuroblasts

Author

Christoph W. Turck, Lily Yeh Jan, Gaia Tavosanis, Yuh Nung Jan, and Claudia Petritsch

Subjects

Embryo, Nonmammalian, animal structures, Immunoblotting, Cell Cycle Proteins, Spindle Apparatus, Cell fate determination, Biology, medicine.disease_cause, General Biochemistry, Genetics and Molecular Biology, Immunoenzyme Techniques, Neuroblast, Cell Movement, Protein targeting, Myosin, medicine, Animals, Drosophila Proteins, Molecular Biology, Mitosis, Actin, Neurons, Myosin Heavy Chains, Neuropeptides, Intracellular Signaling Peptides and Proteins, Signal transducing adaptor protein, Cell Polarity, Biological Transport, Cell Differentiation, Cell Biology, Cell biology, Cytoskeletal Proteins, Drosophila melanogaster, embryonic structures, RNA Interference, Apical complex, Carrier Proteins, Cell Division, Developmental Biology

Abstract

Asymmetric cell divisions generate cellular diversity. In Drosophila , embryonic neuroblasts target cell fate determinants basally, rotate their spindles by 90° to align with the apical-basal axis, and divide asymmetrically in a stem cell-like fashion. In this process, apically localized Bazooka recruits Inscuteable and other proteins to form an apical complex, which then specifies spindle orientation and basal localization of the cell fate determinants and their adapter proteins such as Miranda. Here we report that Miranda localization requires the unconventional myosin VI Jaguar (Jar). In jar null mutant embryos, Miranda is delocalized and the spindle is misoriented, but the Inscuteable crescent remains apical. Miranda directly binds to Jar, raising the possibility that Miranda and its associated proteins are translocated basally by this actin-based motor. Our studies demonstrate that a class VI myosin is necessary for basal protein targeting and spindle orientation in neuroblasts.

14. Molecular Remodeling of the Presynaptic Active Zone of Drosophila Photoreceptors via Activity-Dependent Feedback

Author

Atsushi Sugie, Takashi Suzuki, Satoko Hakeda-Suzuki, Gaia Tavosanis, Emiko Suzuki, Mai Shimozono, Marion Silies, and Christoph Möhl

Subjects

Liprin-alpha protein, Drosophila, GAL4 protein, Drosophila, genetics [Luminescent Proteins], Ion Channels, genetics [Drosophila Proteins], classification [Photoreceptor Cells, Invertebrate], Postsynaptic potential, Drosophila Proteins, metabolism [Transcription Factors], metabolism [Phosphoproteins], TRPA1 Cation Channel, Feedback, Physiological, General Neuroscience, Intracellular Signaling Peptides and Proteins, Wnt signaling pathway, Depolarization, ultrastructure [Presynaptic Terminals], genetics [Transcription Factors], Phenotype, Drosophila, Photoreceptor Cells, Invertebrate, Presynaptic active zone, Signal Transduction, TrpA1 protein, Drosophila, Neuroscience(all), metabolism [TRPC Cation Channels], BRP protein, Drosophila, Presynaptic Terminals, metabolism [Drosophila Proteins], Mice, Transgenic, Sensory system, physiology [Presynaptic Terminals], Biology, genetics [Signal Transduction], Models, Biological, Microscopy, Electron, Transmission, Microtubule, Animals, ddc:610, Active zone, metabolism [Luminescent Proteins], Ion channel, TRPC Cation Channels, Phosphoproteins, metabolism [Photoreceptor Cells, Invertebrate], physiology [Feedback, Physiological], Luminescent Proteins, ultrastructure [Synapses], Synapses, sense organs, physiology [Synapses], Neuroscience, cytology [Photoreceptor Cells, Invertebrate], Photic Stimulation, Transcription Factors

Abstract

SummaryNeural activity contributes to the regulation of the properties of synapses in sensory systems, allowing for adjustment to a changing environment. Little is known about how synaptic molecular components are regulated to achieve activity-dependent plasticity at central synapses. Here, we found that after prolonged exposure to natural ambient light the presynaptic active zone in Drosophila photoreceptors undergoes reversible remodeling, including loss of Bruchpilot, DLiprin-α, and DRBP, but not of DSyd-1 or Cacophony. The level of depolarization of the postsynaptic neurons is critical for the light-induced changes in active zone composition in the photoreceptors, indicating the existence of a feedback signal. In search of this signal, we have identified a crucial role of microtubule meshwork organization downstream of the divergent canonical Wnt pathway, potentially via Kinesin-3 Imac. These data reveal that active zone composition can be regulated in vivo and identify the underlying molecular machinery.