Your search keyword '"Meinertzhagen IA"' showing total 180 results

1. Daily changes among the PDH-immunoreactive neurites in the medulla of the optic lobe in the housefly, Musca domestica

Author

Shimohigashi, M, primary and Meinertzhagen, IA, additional

Published

1999

2. The larval brain of Drosophila: a 3-D database

Author

Meinertzhagen, IA, primary, Horne, JA, additional, Fröhlich, A, additional, and Sun, XJ, additional

Published

1999

3. Monopolar cell axons in the first optic neuropil of the housefly, Musca domestica L., undergo daily fluctuations in diameter that have a circadian basis

Author

Pyza, E, primary and Meinertzhagen, IA, additional

Published

1995

4. Terminal degeneration and synaptic disassembly following receptor photoablation in the retina of the fly's compound eye

Author

Brandstatter, JH, primary, Shaw, SR, additional, and Meinertzhagen, IA, additional

Published

1991

5. Quantitative features of synapse formation in the fly's visual system. I. The presynaptic photoreceptor terminal

Author

Frohlich, A, primary and Meinertzhagen, IA, additional

Published

1983

6. Deep homologies in chordate caudal central nervous systems.

Author

Kourakis MJ, Ryan K, Newman-Smith ED, Meinertzhagen IA, and Smith WC

Abstract

Invertebrate chordates, such as the tunicate Ciona , can offer insight into the evolution of the chordate phylum. Anatomical features that are shared between invertebrate chordates and vertebrates may be taken as evidence of their presence in a common chordate ancestor. The central nervous systems of Ciona larvae and vertebrates share a similar anatomy despite the Ciona CNS having ~180 neurons. However, the depth of conservation between the Ciona CNS and those in vertebrates is not resolved. The Ciona caudal CNS, while appearing spinal cord-like, has hitherto been thought to lack motor neurons, bringing into question its homology with the vertebrate spinal cord. We show here that the Ciona larval caudal CNS does, in fact, have functional motor neurons along its length, pointing to the presence of a spinal cord-like structure at the base of the chordates. We extend our analysis of shared CNS anatomy further to explore the Ciona "motor ganglion", which has been proposed to be a homolog of the vertebrate hindbrain, spinal cord, or both. We find that a cluster of neurons in the dorsal motor ganglion shares anatomical location, developmental pathway, neural circuit architecture, and gene expression with the vertebrate cerebellum. However, functionally, the Ciona cluster appears to have more in common with vertebrate cerebellum-like structures, insofar as it receives and processes direct sensory input. These findings are consistent with earlier speculation that the cerebellum evolved from a cerebellum-like structure, and suggest that the latter structure was present in the dorsal hindbrain of a common chordate ancestor.

Published

2024

7. En bloc preparation of Drosophila brains enables high-throughput FIB-SEM connectomics.

Author

Lu Z, Xu CS, Hayworth KJ, Pang S, Shinomiya K, Plaza SM, Scheffer LK, Rubin GM, Hess HF, Rivlin PK, and Meinertzhagen IA

Subjects

Animals, Microscopy, Electron, Scanning, Volume Electron Microscopy, Synapses physiology, Brain physiology, Drosophila physiology, Connectome

Abstract

Deriving the detailed synaptic connections of an entire nervous system is the unrealized goal of the nascent field of connectomics. For the fruit fly Drosophila , in particular, we need to dissect the brain, connectives, and ventral nerve cord as a single continuous unit, fix and stain it, and undertake automated segmentation of neuron membranes. To achieve this, we designed a protocol using progressive lowering of temperature dehydration (PLT), a technique routinely used to preserve cellular structure and antigenicity. We combined PLT with low temperature en bloc staining (LTS) and recover fixed neurons as round profiles with darkly stained synapses, suitable for machine segmentation and automatic synapse detection. Here we report three different PLT-LTS methods designed to meet the requirements for FIB-SEM imaging of the Drosophila brain. These requirements include: good preservation of ultrastructural detail, high level of en bloc staining, artifact-free microdissection, and smooth hot-knife cutting to reduce the brain to dimensions suited to FIB-SEM. In addition to PLT-LTS, we designed a jig to microdissect and pre-fix the fly's delicate brain and central nervous system. Collectively these methods optimize morphological preservation, allow us to image the brain usually at 8 nm per voxel, and simultaneously speed the formerly slow rate of FIB-SEM imaging., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Lu, Xu, Hayworth, Pang, Shinomiya, Plaza, Scheffer, Rubin, Hess, Rivlin and Meinertzhagen.)

Published

2022

8. Neuronal circuits integrating visual motion information in Drosophila melanogaster.

Author

Shinomiya K, Nern A, Meinertzhagen IA, Plaza SM, and Reiser MB

Subjects

Animals, Interneurons physiology, Neurons physiology, Visual Pathways physiology, Drosophila melanogaster physiology, Motion Perception physiology

Abstract

The detection of visual motion enables sophisticated animal navigation, and studies on flies have provided profound insights into the cellular and circuit bases of this neural computation. The fly's directionally selective T4 and T5 neurons encode ON and OFF motion, respectively. Their axons terminate in one of the four retinotopic layers in the lobula plate, where each layer encodes one of the four directions of motion. Although the input circuitry of the directionally selective neurons has been studied in detail, the synaptic connectivity of circuits integrating T4/T5 motion signals is largely unknown. Here, we report a 3D electron microscopy reconstruction, wherein we comprehensively identified T4/T5's synaptic partners in the lobula plate, revealing a diverse set of new cell types and attributing new connectivity patterns to the known cell types. Our reconstruction explains how the ON- and OFF-motion pathways converge. T4 and T5 cells that project to the same layer connect to common synaptic partners and comprise a core motif together with bilayer interneurons, detailing the circuit basis for computing motion opponency. We discovered pathways that likely encode new directions of motion by integrating vertical and horizontal motion signals from upstream T4/T5 neurons. Finally, we identify substantial projections into the lobula, extending the known motion pathways and suggesting that directionally selective signals shape feature detection there. The circuits we describe enrich the anatomical basis for experimental and computations analyses of motion vision and bring us closer to understanding complete sensory-motor pathways., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

9. Presynaptic Mitochondrial Volume and Packing Density Scale with Presynaptic Power Demand.

Author

Justs KA, Lu Z, Chouhan AK, Borycz JA, Lu Z, Meinertzhagen IA, and Macleod GT

Subjects

Animals, Drosophila, Female, Mitochondria physiology, Synaptic Transmission physiology, Brain physiology, Energy Metabolism physiology, Mitochondrial Size physiology, Motor Neurons physiology, Presynaptic Terminals physiology

Abstract

Stable neural function requires an energy supply that can meet the intense episodic power demands of neuronal activity. Neurons have presumably optimized the volume of their bioenergetic machinery to ensure these power demands are met, but the relationship between presynaptic power demands and the volume available to the bioenergetic machinery has never been quantified. Here, we estimated the power demands of six motor nerve terminals in female Drosophila larvae through direct measurements of neurotransmitter release and Ca 2+ entry, and via theoretical estimates of Na + entry and power demands at rest. Electron microscopy revealed that terminals with the highest power demands contained the greatest volume of mitochondria, indicating that mitochondria are allocated according to presynaptic power demands. In addition, terminals with the greatest power demand-to-volume ratio (∼66 nmol·min -1 ·µl -1 ) harbor the largest mitochondria packed at the greatest density. If we assume sequential and complete oxidation of glucose by glycolysis and oxidative phosphorylation, then these mitochondria are required to produce ATP at a rate of 52 nmol·min -1 ·µl -1 at rest, rising to 963 during activity. Glycolysis would contribute ATP at 0.24 nmol·min -1 ·µl -1 of cytosol at rest, rising to 4.36 during activity. These data provide a quantitative framework for presynaptic bioenergetics in situ , and reveal that, beyond an immediate capacity to accelerate ATP output from glycolysis and oxidative phosphorylation, over longer time periods presynaptic terminals optimize mitochondrial volume and density to meet power demand. SIGNIFICANCE STATEMENT The remarkable energy demands of the brain are supported by the complete oxidation of its fuel but debate continues regarding a division of labor between glycolysis and oxidative phosphorylation across different cell types. Here, we exploit the neuromuscular synapse, a model for studying neurophysiology, to elucidate fundamental aspects of neuronal energy metabolism that ultimately constrain rates of neural processing. We quantified energy production rates required to sustain activity at individual nerve terminals and compared these with the volume capable of oxidative phosphorylation (mitochondria) and glycolysis (cytosol). We find strong support for oxidative phosphorylation playing a primary role in presynaptic terminals and provide the first in vivo estimates of energy production rates per unit volume of presynaptic mitochondria and cytosol., (Copyright © 2022 the authors.)

Published

2022

10. A connectome is not enough - what is still needed to understand the brain of Drosophila?

Author

Scheffer LK and Meinertzhagen IA

Subjects

Animals, Brain, Drosophila, Drosophila melanogaster, Neurons, Connectome

Abstract

Understanding the structure and operation of any nervous system has been a subject of research for well over a century. A near-term opportunity in this quest is to understand the brain of a model species, the fruit fly Drosophila melanogaster. This is an enticing target given its relatively small size (roughly 200,000 neurons), coupled with the behavioral richness that this brain supports, and the wide variety of techniques now available to study both brain and behavior. It is clear that within a few years we will possess a connectome for D. melanogaster: an electron-microscopy-level description of all neurons and their chemical synaptic connections. Given what we will soon have, what we already know and the research that is currently underway, what more do we need to know to enable us to understand the fly's brain? Here, we itemize the data we will need to obtain, collate and organize in order to build an integrated model of the brain of D. melanogaster., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2021. Published by The Company of Biologists Ltd.)

Published

2021

11. Ultrastructural 3D reconstruction of the smallest known insect photoreceptors: The stemmata of a first instar larva of Strepsiptera (Hexapoda).

Author

Fischer S, Laue M, Müller CHG, Meinertzhagen IA, and Pohl H

Subjects

Animals, Insecta, Larva, Photoreceptor Cells, Holometabola, Imaging, Three-Dimensional

Abstract

Stemmata of strepsipteran insects represent the smallest arthropod eyes known, having photoreceptors which form fused rhabdoms measuring an average size of 1.69 × 1.21 × 1.04 μm and each occupying a volume of only 0.97-1.16 μm 3 . The morphology of the stemmata of the extremely miniaturized first instar larva of Stylops ovinae (Strepsiptera, Stylopidae) was investigated using serial-sectioning transmission electron microscopy (ssTEM). Our 3D reconstruction revealed that, despite different proportions, all three stemmata maintain the same organization: a biconvex corneal lens, four corneagenous cells and five photoreceptor (retinula) cells. No pigment-containing cell-types were found to adjoin the corneagenous cells. Whereas the retinula cells are adapted to the limited space by having laterally bulged median regions, containing mitochondria and the smallest nuclei yet reported for arthropods (1.37 μm 3 ), special adaptations are found in the corneagenous cells which have cell volumes down to 1 μm 3 . The corneagenous cells lack nuclei and pigment granules and bear only a few mitochondria (up to three) or none at all. Morphological adaptations due to miniaturization are discussed in the context of photoreceptor function and the visual needs of the larva., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

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. Control of Synaptic Specificity by Establishing a Relative Preference for Synaptic Partners.

Author

Xu C, Theisen E, Maloney R, Peng J, Santiago I, Yapp C, Werkhoven Z, Rumbaut E, Shum B, Tarnogorska D, Borycz J, Tan L, Courgeon M, Griffin T, Levin R, Meinertzhagen IA, de Bivort B, Drugowitsch J, and Pecot MY

Published

2020

14. Neuronal Glutamatergic Synaptic Clefts Alkalinize Rather Than Acidify during Neurotransmission.

Author

Stawarski M, Hernandez RX, Feghhi T, Borycz JA, Lu Z, Agarwal AB, Reihl KD, Tavora R, Lau AWC, Meinertzhagen IA, Renden R, and Macleod GT

Subjects

Animals, Drosophila, Female, Hydrogen-Ion Concentration, Neuronal Plasticity physiology, Synaptic Vesicles metabolism, Glutamic Acid metabolism, Neuromuscular Junction metabolism, Neurons metabolism, Synaptic Transmission physiology

Abstract

The dogma that the synaptic cleft acidifies during neurotransmission is based on the corelease of neurotransmitters and protons from synaptic vesicles, and is supported by direct data from sensory ribbon-type synapses. However, it is unclear whether acidification occurs at non-ribbon-type synapses. Here we used genetically encoded fluorescent pH indicators to examine cleft pH at conventional neuronal synapses. At the neuromuscular junction of female Drosophila larvae, we observed alkaline spikes of over 1 log unit during fictive locomotion in vivo. Ex vivo , single action potentials evoked alkalinizing pH transients of only ∼0.01 log unit, but these transients summated rapidly during burst firing. A chemical pH indicator targeted to the cleft corroborated these findings. Cleft pH transients were dependent on Ca 2+ movement across the postsynaptic membrane, rather than neurotransmitter release per se, a result consistent with cleft alkalinization being driven by the Ca 2+ /H + antiporting activity of the plasma membrane Ca 2+ -ATPase at the postsynaptic membrane. Targeting the pH indicators to the microenvironment of the presynaptic voltage gated Ca 2+ channels revealed that alkalinization also occurred within the cleft proper at the active zone and not just within extrasynaptic regions. Application of the pH indicators at the mouse calyx of Held, a mammalian central synapse, similarly revealed cleft alkalinization during burst firing in both males and females. These findings, made at two quite different non-ribbon type synapses, suggest that cleft alkalinization during neurotransmission, rather than acidification, is a generalizable phenomenon across conventional neuronal synapses. SIGNIFICANCE STATEMENT Neurotransmission is highly sensitive to the pH of the extracellular milieu. This is readily evident in the neurological symptoms that accompany systemic acid/base imbalances. Imaging data from sensory ribbon-type synapses show that neurotransmission itself can acidify the synaptic cleft, likely due to the corelease of protons and glutamate. It is not clear whether the same phenomenon occurs at conventional neuronal synapses due to the difficulties in collecting such data. If it does occur, it would provide for an additional layer of activity-dependent modulation of neurotransmission. Our findings of alkalinization, rather than acidification, within the cleft of two different neuronal synapses encourages a reassessment of the scope of activity-dependent pH influences on neurotransmission and short-term synaptic plasticity., (Copyright © 2020 the authors.)

Published

2020

15. Novel type of sub-retinal pigment shield in the miniaturized compound eye of Trichogramma evanescens.

Author

Mohr T, Meinertzhagen IA, and Fischer S

Subjects

Animals, Microscopy, Electron, Transmission, Retinal Pigments, Wasps, Compound Eye, Arthropod cytology, Compound Eye, Arthropod ultrastructure, Retina cytology, Retina ultrastructure

Abstract

Pigment granules, found in different cell types of the retina in insect compound eyes, fulfill important functions. They isolate the individual ommatidia from stray light, regulate the angular sensitivity, and restrict the light that reaches the photoreceptor according to ambient light intensities. Descriptions of pigment cells within the retina are included in ultrastructural eye descriptions, but knowledge of pigment cell types beneath the retina and basal matrix (BM) are relatively limited in insects. In the miniaturized parasitoid wasp Trichogramma evanescens Westwood 1833, a sub-retinal pigment shield is formed by pigment-bearing cells, which appear in two-dimensional TEM sections to form a separate population beneath the BM. By using three-dimensional reconstructions of serial-section transmission electron microscopy, it was possible to reveal that the sub-retinal pigment shield of T. evanescens is not formed by a separate cell type, but by extensions of the lateral rim pigment cells that penetrate gaps in the BM. The reconstruction is supported by evidence from a statistical analysis of pigment granule volumes of all pigment bearing cell types in the retina and rim region. The study reveals the first known case of the participation of lateral rim cells in a sub-retinal pigment shield in an insect eye. As neither pigmented extensions of secondary pigment cells, nor pigment granules in the extensions of the cone cell projections are present above the BM in T. evanescens, the sub-retinal extensions of the lateral rim cells can be seen as a functional adaptation to miniaturization in order to maintain a proximal shielding function., (© 2019 Wiley Periodicals, Inc.)

Published

2020

16. The Organization of the Second Optic Chiasm of the Drosophila Optic Lobe.

Author

Shinomiya K, Horne JA, McLin S, Wiederman M, Nern A, Plaza SM, and Meinertzhagen IA

Subjects

Animals, Axons physiology, Drosophila, Microscopy, Electron, Scanning, Neurons cytology, Neurons physiology, Optic Chiasm physiology, Optic Lobe, Nonmammalian physiology, Visual Pathways physiology, Optic Chiasm anatomy & histology, Optic Lobe, Nonmammalian anatomy & histology, Visual Pathways anatomy & histology

Abstract

Visual pathways from the compound eye of an insect relay to four neuropils, successively the lamina, medulla, lobula, and lobula plate in the underlying optic lobe. Among these neuropils, the medulla, lobula, and lobula plate are interconnected by the complex second optic chiasm, through which the anteroposterior axis undergoes an inversion between the medulla and lobula. Given their complex structure, the projection patterns through the second optic chiasm have so far lacked critical analysis. By densely reconstructing axon trajectories using a volumetric scanning electron microscopy (SEM) technique, we reveal the three-dimensional structure of the second optic chiasm of Drosophila melanogaster , which comprises interleaving bundles and sheets of axons insulated from each other by glial sheaths. These axon bundles invert their horizontal sequence in passing between the medulla and lobula. Axons connecting the medulla and lobula plate are also bundled together with them but do not decussate the sequence of their horizontal positions. They interleave with sheets of projection neuron axons between the lobula and lobula plate, which also lack decussations. We estimate that approximately 19,500 cells per hemisphere, about two thirds of the optic lobe neurons, contribute to the second chiasm, most being Tm cells, with an estimated additional 2,780 T4 and T5 cells each. The chiasm mostly comprises axons and cell body fibers, but also a few synaptic elements. Based on our anatomical findings, we propose that a chiasmal structure between the neuropils is potentially advantageous for processing complex visual information in parallel. The EM reconstruction shows not only the structure of the chiasm in the adult brain, the previously unreported main topic of our study, but also suggest that the projection patterns of the neurons comprising the chiasm may be determined by the proliferation centers from which the neurons develop. Such a complex wiring pattern could, we suggest, only have arisen in several evolutionary steps., (Copyright © 2019 Shinomiya, Horne, McLin, Wiederman, Nern, Plaza and Meinertzhagen.)

Published

2019

17. The Fly Brain Atlas.

Author

Scheffer LK and Meinertzhagen IA

Subjects

Animals, Behavior, Animal physiology, Brain cytology, Brain physiology, Computational Biology, Drosophila cytology, Drosophila genetics, Gene Expression, Genes, Reporter, Microscopy, Electron, Scanning methods, Microscopy, Fluorescence, Neuroanatomy, Neurons metabolism, Neurons ultrastructure, Synapses physiology, Synapses ultrastructure, Drosophila physiology, Neurons cytology

Abstract

The brain's synaptic networks endow an animal with powerfully adaptive biological behavior. Maps of such synaptic circuits densely reconstructed in those model brains that can be examined and manipulated by genetic means offer the best prospect for understanding the underlying biological bases of behavior. That prospect is now technologically feasible and a scientifically enabling possibility in neurobiology, much as genomics has been in molecular biology and genetics. In Drosophila , two major advances are in electron microscopic technology, using focused ion beam-scanning electron microscopy (FIB-SEM) milling to capture and align digital images, and in computer-aided reconstruction of neuron morphologies. The last decade has witnessed enormous progress in detailed knowledge of the actual synaptic circuits formed by real neurons. Advances in various brain regions that heralded identification of the motion-sensing circuits in the optic lobe are now extending to other brain regions, with the prospect of encompassing the fly's entire nervous system, both brain and ventral nerve cord.

Published

2019

18. Control of Synaptic Specificity by Establishing a Relative Preference for Synaptic Partners.

Author

Xu C, Theisen E, Maloney R, Peng J, Santiago I, Yapp C, Werkhoven Z, Rumbaut E, Shum B, Tarnogorska D, Borycz J, Tan L, Courgeon M, Griffin T, Levin R, Meinertzhagen IA, de Bivort B, Drugowitsch J, and Pecot MY

Subjects

Animals, Animals, Genetically Modified, Drosophila Proteins genetics, Drosophila melanogaster, Immunoglobulins genetics, Membrane Proteins genetics, Neurons cytology, Optic Lobe, Nonmammalian cytology, Protein Interaction Maps, Drosophila Proteins metabolism, Immunoglobulins metabolism, Membrane Proteins metabolism, Neurons metabolism, Optic Lobe, Nonmammalian metabolism, Synapses metabolism

Abstract

The ability of neurons to identify correct synaptic partners is fundamental to the proper assembly and function of neural circuits. Relative to other steps in circuit formation such as axon guidance, our knowledge of how synaptic partner selection is regulated is severely limited. Drosophila Dpr and DIP immunoglobulin superfamily (IgSF) cell-surface proteins bind heterophilically and are expressed in a complementary manner between synaptic partners in the visual system. Here, we show that in the lamina, DIP mis-expression is sufficient to promote synapse formation with Dpr-expressing neurons and that disrupting DIP function results in ectopic synapse formation. These findings indicate that DIP proteins promote synapses to form between specific cell types and that in their absence, neurons synapse with alternative partners. We propose that neurons have the capacity to synapse with a broad range of cell types and that synaptic specificity is achieved by establishing a preference for specific partners., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

19. Neuronal identity: the neuron types of a simple chordate sibling, the tadpole larva of Ciona intestinalis.

Author

Ryan K and Meinertzhagen IA

Subjects

Animals, Ciona intestinalis, Humans, Larva, Siblings, Neurons

Abstract

Neurons of the sparsely populated nervous system of the tadpole larva in the tunicate Ciona intestinalis, a chordate sibling, are known from sporadic previous studies but especially two recent reports that document the connectome of both the central and peripheral nervous systems at EM level. About 330 CNS cells comprise mostly ciliated ependymal cells, with ∼180 neurons that constitute about 50 morphologically distinguishable types. The neurons reveal various chordate characters amid many features that are idiosyncratic. Most neurons are ciliated and lack dendrites, some even lack an axon. Synapses mostly form en passant between axons, and resemble those in basal invertebrates; some are dyads and all have heterogenous synaptic vesicle populations. Each neuron has on average 49 synapses with other cells; these constitute a synaptic network of unpredicted complexity., (Crown Copyright © 2018. Published by Elsevier Ltd. All rights reserved.)

Published

2019

20. Transcriptional Feedback Links Lipid Synthesis to Synaptic Vesicle Pools in Drosophila Photoreceptors.

Author

Tsai JW, Kostyleva R, Chen PL, Rivas-Serna IM, Clandinin MT, Meinertzhagen IA, and Clandinin TR

Subjects

Animals, Drosophila melanogaster, Sterol Regulatory Element Binding Proteins metabolism, Tetraspanins metabolism, Transcriptional Activation, Feedback, Physiological, Phospholipids biosynthesis, Photoreceptor Cells, Invertebrate metabolism, Synaptic Vesicles metabolism

Abstract

Neurons can maintain stable synaptic connections across adult life. However, the signals that regulate expression of synaptic proteins in the mature brain are incompletely understood. Here, we describe a transcriptional feedback loop between the biosynthesis and repertoire of specific phospholipids and the synaptic vesicle pool in adult Drosophila photoreceptors. Mutations that disrupt biosynthesis of a subset of phospholipids cause degeneration of the axon terminal and loss of synaptic vesicles. Although degeneration of the axon terminal is dependent on neural activity, activation of sterol regulatory element binding protein (SREBP) is both necessary and sufficient to cause synaptic vesicle loss. Our studies demonstrate that SREBP regulates synaptic vesicle levels by interacting with tetraspanins, critical organizers of membranous organelles. SREBP is an evolutionarily conserved regulator of lipid biosynthesis in non-neuronal cells; our studies reveal a surprising role for this feedback loop in maintaining synaptic vesicle pools in the adult brain., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

21. Differential Adhesion Determines the Organization of Synaptic Fascicles in the Drosophila Visual System.

Author

Schwabe T, Borycz JA, Meinertzhagen IA, and Clandinin TR

Published

2019

22. Comparisons between the ON- and OFF-edge motion pathways in the Drosophila brain.

Author

Shinomiya K, Huang G, Lu Z, Parag T, Xu CS, Aniceto R, Ansari N, Cheatham N, Lauchie S, Neace E, Ogundeyi O, Ordish C, Peel D, Shinomiya A, Smith C, Takemura S, Talebi I, Rivlin PK, Nern A, Scheffer LK, Plaza SM, and Meinertzhagen IA

Subjects

Animals, Connectome, Crosses, Genetic, Dendrites metabolism, Female, Homozygote, Models, Neurological, Neurons metabolism, Photoreceptor Cells, Invertebrate physiology, Synapses physiology, Brain physiology, Drosophila melanogaster physiology, Image Processing, Computer-Assisted methods, Motion Perception, Optic Lobe, Nonmammalian physiology

Abstract

Understanding the circuit mechanisms behind motion detection is a long-standing question in visual neuroscience. In Drosophila melanogaster , recently discovered synapse-level connectomes in the optic lobe, particularly in ON-pathway (T4) receptive-field circuits, in concert with physiological studies, suggest a motion model that is increasingly intricate when compared with the ubiquitous Hassenstein-Reichardt model. By contrast, our knowledge of OFF-pathway (T5) has been incomplete. Here, we present a conclusive and comprehensive connectome that, for the first time, integrates detailed connectivity information for inputs to both the T4 and T5 pathways in a single EM dataset covering the entire optic lobe. With novel reconstruction methods using automated synapse prediction suited to such a large connectome, we successfully corroborate previous findings in the T4 pathway and comprehensively identify inputs and receptive fields for T5. Although the two pathways are probably evolutionarily linked and exhibit many similarities, we uncover interesting differences and interactions that may underlie their distinct functional properties., Competing Interests: KS, GH, ZL, TP, CX, RA, NA, NC, SL, EN, OO, CO, DP, AS, CS, ST, IT, PR, AN, LS, SP, IM No competing interests declared, (© 2019, Shinomiya et al.)

Published

2019

23. Three-dimensional ultrastructural organization of the ommatidium of the minute parasitoid wasp Trichogramma evanescens.

Author

Fischer S, Lu Z, and Meinertzhagen IA

Subjects

Animals, Body Size, Male, Microscopy, Electron, Transmission, Compound Eye, Arthropod ultrastructure, Wasps ultrastructure

Abstract

Existing information on insect compound eyes is mainly limited to two-dimensional information derived from histological or ultrathin sections. These allow a basic description of eye morphology, but are limited in z-axis resolution because of the section thickness or intervals between sections, so that accurate volumetric information cannot be generated. Here we use serial-sectioning transmission electron microscopy to present a 3-D reconstruction at ultrastructural level of a complete ommatidium of a miniaturized insect compound eye. Besides the general presentation of the three dimensional arrangement of the different cell types within the ommatidium, the reconstruction allowed volumetric measurements and numerical analyses to be undertaken, revealing new insights into the number, size and distribution of cell organelles in insect ommatidia. Morphological features that can be related to miniaturization, namely the dimensions and displacement of nuclei, reduction of average pigment granule volume and loss of pigment granules in the terminals of the cone cells, the impact of metabolic activity of cell types on miniaturization, as well as maintenance of rhabdomere volume and limits to its miniaturization, are all discussed., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2019

24. A resource for the Drosophila antennal lobe provided by the connectome of glomerulus VA1v.

Author

Horne JA, Langille C, McLin S, Wiederman M, Lu Z, Xu CS, Plaza SM, Scheffer LK, Hess HF, and Meinertzhagen IA

Subjects

Animals, Arthropod Antennae ultrastructure, Female, Nerve Net physiology, Synapses physiology, Synapses ultrastructure, Arthropod Antennae innervation, Connectome, Drosophila melanogaster physiology, Olfactory Receptor Neurons physiology

Abstract

Using FIB-SEM we report the entire synaptic connectome of glomerulus VA1v of the right antennal lobe in Drosophila melanogaster . Within the glomerulus we densely reconstructed all neurons, including hitherto elusive local interneurons. The fruitless -positive, sexually dimorphic VA1v included >11,140 presynaptic sites with ~38,050 postsynaptic dendrites. These connected input olfactory receptor neurons (ORNs, 51 ipsilateral, 56 contralateral), output projection neurons (18 PNs), and local interneurons (56 of >150 previously reported LNs). ORNs are predominantly presynaptic and PNs predominantly postsynaptic; newly reported LN circuits are largely an equal mixture and confer extensive synaptic reciprocity, except the newly reported LN2V with input from ORNs and outputs mostly to monoglomerular PNs, however. PNs were more numerous than previously reported from genetic screens, suggesting that the latter failed to reach saturation. We report a matrix of 192 bodies each having > 50 connections; these form 88% of the glomerulus' pre/postsynaptic sites., Competing Interests: JH, CL, SM, MW, ZL, CX, SP, LS, HH, IM No competing interests declared, (© 2018, Horne et al.)

Published

2018

25. The world of the identified or digital neuron.

Author

Meinertzhagen IA

Subjects

Animals, Brain cytology, Brain physiology, Neurons classification, Neurons cytology, Neurons physiology

Abstract

In general, neurons in insects and many other invertebrate groups are individually recognizable, enabling us to assign an index number to specific neurons in a manner which is rarely possible in a vertebrate brain. This endows many studies on insect nervous systems with the opportunity to document neurons with great precision, so that in favourable cases we can return to the same neuron or neuron type repeatedly so as to recognize many separate morphological classes. The visual system of the fly's compound eye particularly provides clear examples of the accuracy of neuron wiring, allowing numerical comparisons between representatives of the same cell type, and estimates of the accuracy of their wiring.

Published

2018

26. Location and functions of Inebriated in the Drosophila eye.

Author

Borycz J, Ziegler A, Borycz JA, Uhlenbrock G, Tapken D, Caceres L, Hollmann M, Hovemann BT, and Meinertzhagen IA

Abstract

Histamine (HA) is a neurotransmitter in arthropod photoreceptors. It is recycled via conjugation to β-alanine to form β-alanylhistamine (carcinine). Conjugation occurs in epithelial glia that surround photoreceptor terminals in the first optic neuropil, and carcinine (CA) is then transported back to photoreceptors and cleaved to liberate HA and β-alanine. The gene Inebriated ( Ine ) encodes an Na + /Cl - -dependent SLC6 family transporter translated as two protein isoforms, long (P1) and short (P2). Photoreceptors specifically express Ine-P2 whereas Ine-P1 is expressed in non-neuronal cells. Both ine 1 and ine 3 have significantly reduced head HA contents compared with wild type, and a smaller increase in head HA after drinking 1% CA. Similarly, uptake of 0.1% CA was reduced in ine 1 and ine 3 mutant synaptosomes, but increased by 90% and 84% respectively for fractions incubated in 0.05% β-Ala, compared with wild type. Screening potential substrates in Ine expressing Xenopus oocytes revealed very little response to carcinine and β-Ala but increased conductance with glycine. Both ine 1 and ine 3 mutant responses in light-dark phototaxis did not differ from wild-type. Collectively our results suggest that Inebriated functions in an adjunct role as a transporter to the previously reported carcinine transporter CarT., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2018. Published by The Company of Biologists Ltd.)

Published

2018

27. Of what use is connectomics? A personal perspective on the Drosophila connectome.

Author

Meinertzhagen IA

Subjects

Animals, Behavior, Animal, Brain anatomy & histology, Brain physiology, Drosophila melanogaster growth & development, Larva anatomy & histology, Larva physiology, Neurons, Connectome, Drosophila melanogaster anatomy & histology, Drosophila melanogaster physiology

Abstract

The brain is a network of neurons and its biological output is behaviour. This is an exciting age, with a growing acknowledgement that the comprehensive compilation of synaptic circuits densely reconstructed in the brains of model species is now both technologically feasible and a scientifically enabling possibility in neurobiology, much as 30 years ago genomics was in molecular biology and genetics. Implemented by huge advances in electron microscope technology, especially focused ion beam-scanning electron microscope (FIB-SEM) milling (see Glossary), image capture and alignment, and computer-aided reconstruction of neuron morphologies, enormous progress has been made in the last decade in the detailed knowledge of the actual synaptic circuits formed by real neurons, in various brain regions of the fly Drosophila It is useful to distinguish synaptic pathways that are major, with 100 or more presynaptic contacts, from those that are minor, with fewer than about 10; most neurites are both presynaptic and postsynaptic, and all synaptic sites have multiple postsynaptic dendrites. Work on Drosophila has spearheaded these advances because cell numbers are manageable, and neuron classes are morphologically discrete and genetically identifiable, many confirmed by reporters. Recent advances are destined within the next few years to reveal the complete connectome in an adult fly, paralleling advances in the larval brain that offer the same prospect possibly within an even shorter time frame. The final amendment and validation of segmented bodies by human proof-readers remains the most time-consuming step, however. The value of a complete connectome in Drosophila is that, by targeting to specific neurons transgenes that either silence or activate morphologically identified circuits, and then identifying the resulting behavioural outcome, we can determine the causal mechanism for behaviour from its loss or gain. More importantly, the connectome reveals hitherto unsuspected pathways, leading us to seek novel behaviours for these. Circuit information will eventually be required to understand how differences between brains underlie differences in behaviour, and especially to herald yet more advanced connectomic strategies for the vertebrate brain, with an eventual prospect of understanding cognitive disorders having a connectomic basis. Connectomes also help us to identify common synaptic circuits in different species and thus to reveal an evolutionary progression in candidate pathways., Competing Interests: Competing interestsThe author declares no competing or financial interests., (© 2018. Published by The Company of Biologists Ltd.)

Published

2018

28. The peripheral nervous system of the ascidian tadpole larva: Types of neurons and their synaptic networks.

Author

Ryan K, Lu Z, and Meinertzhagen IA

Subjects

Animals, Ciona ultrastructure, Larva ultrastructure, Microscopy, Electron, Neural Pathways cytology, Neural Pathways growth & development, Neural Pathways ultrastructure, Neurons ultrastructure, Peripheral Nervous System ultrastructure, Synapses ultrastructure, Ciona cytology, Ciona growth & development, Larva cytology, Neurons cytology, Peripheral Nervous System cytology, Peripheral Nervous System growth & development

Abstract

Physical and chemical cues from the environment are used to direct animal behavior through a complex network of connections originating in exteroceptors. In chordates, mechanosensory and chemosensory neurons of the peripheral nervous system (PNS) must signal to the motor circuits of the central nervous system (CNS) through a series of pathways that integrate and regulate the output to motor neurons (MN); ultimately these drive contraction of the tail and limb muscles. We used serial-section electron microscopy to reconstruct PNS neurons and their hitherto unknown synaptic networks in the tadpole larva of a sibling chordate, the ascidian, Ciona intestinalis. The larva has groups of neurons in its apical papillae, epidermal neurons in the rostral and apical trunk, caudal neurons in the dorsal and ventral epidermis, and a single tail tip neuron. The connectome reveals that the PNS input arises from scattered groups of these epidermal neurons, 54 in total, and has three main centers of integration in the CNS: in the anterior brain vesicle (which additionally receives input from photoreceptors of the ocellus), the motor ganglion (which contains five pairs of MN), and the tail, all of which in turn are themselves interconnected through important functional relay neurons. Some neurons have long collaterals that form autapses. Our study reveals interconnections with other sensory systems, and the exact inputs to the motor system required to regulate contractions in the tail that underlie larval swimming, or to the CNS to regulate substrate preference prior to the induction of larval settlement and metamorphosis., (© 2017 Wiley Periodicals, Inc.)

Published

2018

29. From two to three dimensions: The importance of the third dimension for evaluating the limits to neuronal miniaturization in insects.

Author

Fischer S, Lu Z, and Meinertzhagen IA

Subjects

Animals, Axons ultrastructure, Brain ultrastructure, Cell Nucleus ultrastructure, Cell Size, Imaging, Three-Dimensional, Male, Microscopy, Electron, Transmission, Mitochondria ultrastructure, Neurons ultrastructure, Wasps ultrastructure

Abstract

Most studies dealing with the limits to miniaturization in insect brains have until now relied on information based on data collected in two dimensions: either histological sections imaged by light microscopy, or electron micrographs of single ultrathin sections imaged by transmission electron microscopy (TEM). To test the validity of transferring information gained from two-dimensional images to the third dimension, we examined a 3D image stack from serial-section TEM (ssTEM) of the optic neuropiles of the miniature parasitic wasp Trichogramma brassicae (Bezdenko, 1968). We reinvestigated the proposed lower limit of 2 µm for the diameters of neuronal somata and found average volumes of 6.5 μm 3 for lamina cells and 3.8 μm 3 for medulla cells. We likewise found a limiting factor for the volume of nuclei, which averages 41.9% and 49.2% of the cell body volume, respectively, but that in turn the compactness of heterochromatin was not a limiting factor in the minimal volume of the nuclei. Finally, we also found a minimum axon diameter of 98 nm that could nevertheless accommodate axoplasmic mitochondria. Incorporating the third dimension thus proves critically important in avoiding volumetric misinterpretations of these values. We discuss the limitations of analyzing the effects of miniaturization from profile data of neurons and demonstrate that miniaturization within the nervous system can lie beyond previously described limits and in some cases is already present in the optic lobe neurons of T. brassicae., (© 2017 Wiley Periodicals, Inc.)

Published

2018

30. Drosophila Sidekick is required in developing photoreceptors to enable visual motion detection.

Author

Astigarraga S, Douthit J, Tarnogorska D, Creamer MS, Mano O, Clark DA, Meinertzhagen IA, and Treisman JE

Subjects

Animals, Animals, Genetically Modified, Drosophila Proteins genetics, Drosophila melanogaster genetics, Eye Proteins genetics, Female, Genes, Insect, Male, Mutation, Neural Cell Adhesion Molecules genetics, Photoreceptor Cells, Invertebrate cytology, Synapses metabolism, Visual Pathways cytology, Visual Pathways growth & development, Visual Pathways physiology, Drosophila Proteins physiology, Drosophila melanogaster growth & development, Drosophila melanogaster physiology, Eye Proteins physiology, Motion Perception physiology, Neural Cell Adhesion Molecules physiology, Photoreceptor Cells, Invertebrate physiology

Abstract

The assembly of functional neuronal circuits requires growth cones to extend in defined directions and recognize the correct synaptic partners. Homophilic adhesion between vertebrate Sidekick proteins promotes synapse formation between retinal neurons involved in visual motion detection. We show here that Drosophila Sidekick accumulates in specific synaptic layers of the developing motion detection circuit and is necessary for normal optomotor behavior. Sidekick is required in photoreceptors, but not in their target lamina neurons, to promote the alignment of lamina neurons into columns and subsequent sorting of photoreceptor axons into synaptic modules based on their precise spatial orientation. Sidekick is also localized to the dendrites of the direction-selective T4 and T5 cells, and is expressed in some of their presynaptic partners. In contrast to its vertebrate homologs, Sidekick is not essential for T4 and T5 to direct their dendrites to the appropriate layers or to receive synaptic contacts. These results illustrate a conserved requirement for Sidekick proteins in establishing visual motion detection circuits that is achieved through distinct cellular mechanisms in Drosophila and vertebrates., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2018. Published by The Company of Biologists Ltd.)

Published

2018

31. The comprehensive connectome of a neural substrate for 'ON' motion detection in Drosophila .

Author

Takemura SY, Nern A, Chklovskii DB, Scheffer LK, Rubin GM, and Meinertzhagen IA

Subjects

Animals, Models, Neurological, Connectome, Drosophila melanogaster anatomy & histology, Drosophila melanogaster physiology, Motion Perception, Visual Pathways anatomy & histology, Visual Pathways physiology

Abstract

Analysing computations in neural circuits often uses simplified models because the actual neuronal implementation is not known. For example, a problem in vision, how the eye detects image motion, has long been analysed using Hassenstein-Reichardt (HR) detector or Barlow-Levick (BL) models. These both simulate motion detection well, but the exact neuronal circuits undertaking these tasks remain elusive. We reconstructed a comprehensive connectome of the circuits of Drosophila 's motion-sensing T4 cells using a novel EM technique. We uncover complex T4 inputs and reveal that putative excitatory inputs cluster at T4's dendrite shafts, while inhibitory inputs localize to the bases. Consistent with our previous study, we reveal that Mi1 and Tm3 cells provide most synaptic contacts onto T4. We are, however, unable to reproduce the spatial offset between these cells reported previously. Our comprehensive connectome reveals complex circuits that include candidate anatomical substrates for both HR and BL types of motion detectors.

Published

2017

32. Circuit Homology between Decussating Pathways in the Ciona Larval CNS and the Vertebrate Startle-Response Pathway.

Author

Ryan K, Lu Z, and Meinertzhagen IA

Subjects

Animals, Central Nervous System physiology, Ciona intestinalis growth & development, Connectome, Larva growth & development, Larva physiology, Neural Pathways physiology, Reflex, Startle, Vertebrates physiology, Ciona intestinalis physiology

Abstract

Comparing synaptic circuits and networks between brains of different animal groups helps us derive an understanding of how nervous systems might have evolved. The circuits of the startle response pathway in the brains of tailed vertebrates are known from electrophysiological studies on the giant reticulospinal Mauthner cells (M-cells). To identify morphological counterparts in chordate tunicates, a sister group of vertebrates [1, 2], we have compiled a densely reconstructed connectome (defined in [3]) for the CNS in the tadpole larva of Ciona intestinalis (L.), using ssEM [4]. The dorsal, tubular CNS of the ∼1-mm tadpole larva is built on a similar plan to vertebrates, its neurons distributed rostrocaudally in three centers, a brain vesicle, motor ganglion, and caudal nerve cord [5]. A single pair of descending decussating neurons, ddNs, found in the motor ganglion, have similarities to reticulospinal neurons descending from the vertebrate hindbrain to the spinal cord. The pre- and postsynaptic connections and circuits of these ddNs support their homology with decussating vertebrate M-cells. Network analysis reveals that, like M-cells, ddNs receive mechanosensory input from the peripheral nervous system and provide input to motoneurons, premotor interneurons, and ascending commissural inhibitory neurons (ACINs). These circuits uncover a putative homologous startle network in the Ciona tadpole. However, differences in circuits, including a lack of bilateral symmetry in their network, and convergence of inputs from left and right sides, raise questions about the relationship between form and function, and are a possible outcome of the tiny number of neurons in ascidian larvae., (Crown Copyright © 2017. Published by Elsevier Ltd. All rights reserved.)

Published

2017

33. The CNS connectome of a tadpole larva of Ciona intestinalis (L.) highlights sidedness in the brain of a chordate sibling.

Author

Ryan K, Lu Z, and Meinertzhagen IA

Subjects

Animals, Brain cytology, Ciona intestinalis growth & development, Functional Laterality, Larva cytology, Larva physiology, Microscopy, Electron, Neurons ultrastructure, Organelles ultrastructure, Synapses metabolism, Ciona intestinalis cytology, Ciona intestinalis physiology, Connectome

Abstract

Left-right asymmetries in brains are usually minor or cryptic. We report brain asymmetries in the tiny, dorsal tubular nervous system of the ascidian tadpole larva, Ciona intestinalis . Chordate in body plan and development, the larva provides an outstanding example of brain asymmetry. Although early neural development is well studied, detailed cellular organization of the swimming larva's CNS remains unreported. Using serial-section EM we document the synaptic connectome of the larva's 177 CNS neurons. These formed 6618 synapses including 1772 neuromuscular junctions, augmented by 1206 gap junctions. Neurons are unipolar with at most a single dendrite, and few synapses. Some synapses are unpolarised, others form reciprocal or serial motifs; 922 were polyadic. Axo-axonal synapses predominate. Most neurons have ciliary organelles, and many features lack structural specialization. Despite equal cell numbers on both sides, neuron identities and pathways differ left/right. Brain vesicle asymmetries include a right ocellus and left coronet cells., Competing Interests: The authors declare that no competing interests exist.

Published

2016

34. High-Probability Neurotransmitter Release Sites Represent an Energy-Efficient Design.

Author

Lu Z, Chouhan AK, Borycz JA, Lu Z, Rossano AJ, Brain KL, Zhou Y, Meinertzhagen IA, and Macleod GT

Subjects

Animals, Drosophila melanogaster growth & development, Glutamic Acid metabolism, Larva growth & development, Larva physiology, Drosophila melanogaster physiology, Motor Neurons physiology, Neuromuscular Junction physiology, Presynaptic Terminals physiology, Synaptic Transmission

Abstract

Nerve terminals contain multiple sites specialized for the release of neurotransmitters. Release usually occurs with low probability, a design thought to confer many advantages. High-probability release sites are not uncommon, but their advantages are not well understood. Here, we test the hypothesis that high-probability release sites represent an energy-efficient design. We examined release site probabilities and energy efficiency at the terminals of two glutamatergic motor neurons synapsing on the same muscle fiber in Drosophila larvae. Through electrophysiological and ultrastructural measurements, we calculated release site probabilities to differ considerably between terminals (0.33 versus 0.11). We estimated the energy required to release and recycle glutamate from the same measurements. The energy required to remove calcium and sodium ions subsequent to nerve excitation was estimated through microfluorimetric and morphological measurements. We calculated energy efficiency as the number of glutamate molecules released per ATP molecule hydrolyzed, and high-probability release site terminals were found to be more efficient (0.13 versus 0.06). Our analytical model indicates that energy efficiency is optimal (∼0.15) at high release site probabilities (∼0.76). As limitations in energy supply constrain neural function, high-probability release sites might ameliorate such constraints by demanding less energy. Energy efficiency can be viewed as one aspect of nerve terminal function, in balance with others, because high-efficiency terminals depress significantly during episodic bursts of activity., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2016

35. Connectome studies on Drosophila: a short perspective on a tiny brain.

Author

Meinertzhagen IA

Subjects

Animals, Brain ultrastructure, Connectome methods, Drosophila physiology

Abstract

The brain is a network of neurons, one that generates behaviour, and knowing the former is crucial to understanding the latter. Identifying the exact network of synaptic connections, or connectome, of the fly's central nervous system is now a major objective in Drosophila neurobiology, one that has been initiated in several laboratories, especially the Janelia Research Campus of the Howard Hughes Medical Institute. Progress is most advanced in the optic neuropiles of the visual system. The effort to derive a connectome from these and other neuropile regions is proceeding by various methods of electron microscopy, especially focused-ion beam milling scanning electron microscopy, and relies upon - but is to be carefully distinguished from - published light microscopic methods that reveal the projections of genetically labelled cell types. The latter reveal those neurons that come into close proximity and are therefore candidate synaptic partners. Synaptic partnerships are not in fact reliably revealed by such candidate pairs, anatomical connections often revealing unexpected pathways. Synaptic partnerships identified from ultrastructural features provide a strong heuristic basis to interpret not only functional interactions between identified neurons, but also a powerful means to predict such interactions, and suggest functional pathways not readily predicted from existing experimental evidence. The analysis of circuit function may proceed cell by cell, by examining the behavioural outcome of either interrupting or restoring function to any one element in an anatomically defined circuit, but can be foiled by degeneracy in pathway elements. Circuit information can also be used to identify and analyse circuit motifs, and their role in higher-order network properties. These attempts in Drosophila anticipate parallel attempts in other systems, notably the inner plexiform layer of the vertebrate retina, and augment the one complete connectome already available to us, that available for 30 years in the nematode Caenorhabditis elegans.

Published

2016

36. Mapping chromatic pathways in the Drosophila visual system.

Author

Lin TY, Luo J, Shinomiya K, Ting CY, Lu Z, Meinertzhagen IA, and Lee CH

Subjects

Animals, Animals, Genetically Modified, Drosophila anatomy & histology, Drosophila Proteins genetics, Drosophila Proteins metabolism, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Medulla Oblongata cytology, Microscopy, Confocal, Transcription Factors genetics, Transcription Factors metabolism, Visual Pathways metabolism, Brain Mapping, Color, Neurons metabolism, Neuropil physiology, Photoreceptor Cells, Invertebrate physiology, Visual Pathways cytology

Abstract

In Drosophila, color vision and wavelength-selective behaviors are mediated by the compound eye's narrow-spectrum photoreceptors R7 and R8 and their downstream medulla projection (Tm) neurons Tm5a, Tm5b, Tm5c, and Tm20 in the second optic neuropil or medulla. These chromatic Tm neurons project axons to a deeper optic neuropil, the lobula, which in insects has been implicated in processing and relaying color information to the central brain. The synaptic targets of the chromatic Tm neurons in the lobula are not known, however. Using a modified GFP reconstitution across synaptic partners (GRASP) method to probe connections between the chromatic Tm neurons and 28 known and novel types of lobula neurons, we identify anatomically the visual projection neurons LT11 and LC14 and the lobula intrinsic neurons Li3 and Li4 as synaptic targets of the chromatic Tm neurons. Single-cell GRASP analyses reveal that Li4 receives synaptic contacts from over 90% of all four types of chromatic Tm neurons, whereas LT11 is postsynaptic to the chromatic Tm neurons, with only modest selectivity and at a lower frequency and density. To visualize synaptic contacts at the ultrastructural level, we develop and apply a "two-tag" double-labeling method to label LT11's dendrites and the mitochondria in Tm5c's presynaptic terminals. Serial electron microscopic reconstruction confirms that LT11 receives direct contacts from Tm5c. This method would be generally applicable to map the connections of large complex neurons in Drosophila and other animals., (© 2015 Wiley Periodicals, Inc.)

Published

2016

37. Histamine Recycling Is Mediated by CarT, a Carcinine Transporter in Drosophila Photoreceptors.

Author

Xu Y, An F, Borycz JA, Borycz J, Meinertzhagen IA, and Wang T

Subjects

Animals, Cell Line, Drosophila genetics, Drosophila Proteins genetics, Organic Cation Transporter 1 genetics, Photoreceptor Cells, Invertebrate physiology, Synapses metabolism, Synapses physiology, Synaptic Transmission, Drosophila metabolism, Drosophila Proteins metabolism, Histamine metabolism, Organic Cation Transporter 1 metabolism, Photoreceptor Cells, Invertebrate metabolism

Abstract

Histamine is an important chemical messenger that regulates multiple physiological processes in both vertebrate and invertebrate animals. Even so, how glial cells and neurons recycle histamine remains to be elucidated. Drosophila photoreceptor neurons use histamine as a neurotransmitter, and the released histamine is recycled through neighboring glia, where it is conjugated to β-alanine to form carcinine. However, how carcinine is then returned to the photoreceptor remains unclear. In an mRNA-seq screen for photoreceptor cell-enriched transporters, we identified CG9317, an SLC22 transporter family protein, and named it CarT (Carcinine Transporter). S2 cells that express CarT are able to take up carcinine in vitro. In the compound eye, CarT is exclusively localized to photoreceptor terminals. Null mutations of cart alter the content of histamine and its metabolites. Moreover, null cart mutants are defective in photoreceptor synaptic transmission and lack phototaxis. These findings reveal that CarT is required for histamine recycling at histaminergic photoreceptors and provide evidence for a CarT-dependent neurotransmitter trafficking pathway between glial cells and photoreceptor terminals.

Published

2015

38. Co-localization of Gamma-Aminobutyric Acid and Glutamate in Neurons of the Spider Central Nervous System.

Author

Fabian-Fine R, Meisner S, Torkkeli PH, and Meinertzhagen IA

Subjects

Animals, Esophagus metabolism, Female, Fluorescent Antibody Technique, GABA Plasma Membrane Transport Proteins metabolism, Ganglia, Invertebrate metabolism, Imaging, Three-Dimensional, Muscles metabolism, Muscles ultrastructure, Spiders ultrastructure, Synapses metabolism, Synapses ultrastructure, Central Nervous System metabolism, Glutamic Acid metabolism, Neurons metabolism, Spiders metabolism, gamma-Aminobutyric Acid metabolism

Abstract

Spider sensory neurons with cell bodies close to various sensory organs are innervated by putative efferent axons from the central nervous system (CNS). Light and electronmicroscopic imaging of immunolabeled neurons has demonstrated that neurotransmitters present at peripheral synapses include γ-aminobutyric acid (GABA), glutamate and octopamine. Moreover, electrophysiological studies show that these neurotransmitters modulate the sensitivity of peripheral sensory neurons. Here, we undertook immunocytochemical investigations to characterize GABA and glutamate-immunoreactive neurons in three-dimensional reconstructions of the spider CNS. We document that both neurotransmitters are abundant in morphologically distinct neurons throughout the CNS. Labeling for the vesicular transporters, VGAT for GABA and VGLUT for glutamate, showed corresponding patterns, supporting the specificity of antibody binding. Whereas some neurons displayed strong immunolabeling, others were only weakly labeled. Double labeling showed that a subpopulation of weakly labeled neurons present in all ganglia expresses both GABA and glutamate. Double labeled, strongly and weakly labeled GABA and glutamate immunoreactive axons were also observed in the periphery along muscle fibers and peripheral sensory neurons. Electron microscopic investigations showed presynaptic profiles of various diameters with mixed vesicle populations innervating muscle tissue as well as sensory neurons. Our findings provide evidence that: (1) sensory neurons and muscle fibers are innervated by morphologically distinct, centrally located GABA- and glutamate immunoreactive neurons; (2) a subpopulation of these neurons may co-release both neurotransmitters; and (3) sensory neurons and muscles are innervated by all of these neurochemically and morphologically distinct types of neurons. The biochemical diversity of presynaptic innervation may contribute to how spiders filter natural stimuli and coordinate appropriate response patterns.

Published

2015

39. Migratory neuronal progenitors arise from the neural plate borders in tunicates.

Author

Stolfi A, Ryan K, Meinertzhagen IA, and Christiaen L

Subjects

Animals, Cell Movement, Cell Polarity, Ganglia, Spinal cytology, Larva cytology, Mesoderm cytology, Multipotent Stem Cells cytology, Neural Crest cytology, Neurogenesis, Neurons cytology, Synapses, Tail cytology, Vertebrates, Ciona intestinalis cytology, Neural Plate cytology, Neural Stem Cells cytology

Abstract

The neural crest is an evolutionary novelty that fostered the emergence of vertebrate anatomical innovations such as the cranium and jaws. During embryonic development, multipotent neural crest cells are specified at the lateral borders of the neural plate before delaminating, migrating and differentiating into various cell types. In invertebrate chordates (cephalochordates and tunicates), neural plate border cells express conserved factors such as Msx, Snail and Pax3/7 and generate melanin-containing pigment cells, a derivative of the neural crest in vertebrates. However, invertebrate neural plate border cells have not been shown to generate homologues of other neural crest derivatives. Thus, proposed models of neural crest evolution postulate vertebrate-specific elaborations on an ancestral neural plate border program, through acquisition of migratory capabilities and the potential to generate several cell types. Here we show that a particular neuronal cell type in the tadpole larva of the tunicate Ciona intestinalis, the bipolar tail neuron, shares a set of features with neural-crest-derived spinal ganglia neurons in vertebrates. Bipolar tail neuron precursors derive from caudal neural plate border cells, delaminate and migrate along the paraxial mesoderm on either side of the neural tube, eventually differentiating into afferent neurons that form synaptic contacts with both epidermal sensory cells and motor neurons. We propose that the neural plate borders of the chordate ancestor already produced migratory peripheral neurons and pigment cells, and that the neural crest evolved through the acquisition of a multipotent progenitor regulatory state upstream of multiple, pre-existing neural plate border cell differentiation programs.

Published

2015

40. Synaptic circuits and their variations within different columns in the visual system of Drosophila.

Author

Takemura SY, Xu CS, Lu Z, Rivlin PK, Parag T, Olbris DJ, Plaza S, Zhao T, Katz WT, Umayam L, Weaver C, Hess HF, Horne JA, Nunez-Iglesias J, Aniceto R, Chang LA, Lauchie S, Nasca A, Ogundeyi O, Sigmund C, Takemura S, Tran J, Langille C, Le Lacheur K, McLin S, Shinomiya A, Chklovskii DB, Meinertzhagen IA, and Scheffer LK

Subjects

Animals, Drosophila melanogaster physiology, Synapses physiology, Vision, Ocular physiology

Abstract

We reconstructed the synaptic circuits of seven columns in the second neuropil or medulla behind the fly's compound eye. These neurons embody some of the most stereotyped circuits in one of the most miniaturized of animal brains. The reconstructions allow us, for the first time to our knowledge, to study variations between circuits in the medulla's neighboring columns. This variation in the number of synapses and the types of their synaptic partners has previously been little addressed because methods that visualize multiple circuits have not resolved detailed connections, and existing connectomic studies, which can see such connections, have not so far examined multiple reconstructions of the same circuit. Here, we address the omission by comparing the circuits common to all seven columns to assess variation in their connection strengths and the resultant rates of several different and distinct types of connection error. Error rates reveal that, overall, <1% of contacts are not part of a consensus circuit, and we classify those contacts that supplement (E+) or are missing from it (E-). Autapses, in which the same cell is both presynaptic and postsynaptic at the same synapse, are occasionally seen; two cells in particular, Dm9 and Mi1, form ≥ 20-fold more autapses than do other neurons. These results delimit the accuracy of developmental events that establish and normally maintain synaptic circuits with such precision, and thereby address the operation of such circuits. They also establish a precedent for error rates that will be required in the new science of connectomics.

Published

2015

41. A common evolutionary origin for the ON- and OFF-edge motion detection pathways of the Drosophila visual system.

Author

Shinomiya K, Takemura SY, Rivlin PK, Plaza SM, Scheffer LK, and Meinertzhagen IA

Subjects

Animals, Choline O-Acetyltransferase metabolism, Drosophila, Neurons classification, Vesicular Inhibitory Amino Acid Transport Proteins metabolism, Biological Evolution, Motion Perception physiology, Neurons physiology, Neuropil physiology, Orientation physiology, Visual Pathways physiology

Abstract

Synaptic circuits for identified behaviors in the Drosophila brain have typically been considered from either a developmental or functional perspective without reference to how the circuits might have been inherited from ancestral forms. For example, two candidate pathways for ON- and OFF-edge motion detection in the visual system act via circuits that use respectively either T4 or T5, two cell types of the fourth neuropil, or lobula plate (LOP), that exhibit narrow-field direction-selective responses and provide input to wide-field tangential neurons. T4 or T5 both have four subtypes that terminate one each in the four strata of the LOP. Representatives are reported in a wide range of Diptera, and both cell types exhibit various similarities in: (1) the morphology of their dendritic arbors; (2) their four morphological and functional subtypes; (3) their cholinergic profile in Drosophila; (4) their input from the pathways of L3 cells in the first neuropil, or lamina (LA), and by one of a pair of LA cells, L1 (to the T4 pathway) and L2 (to the T5 pathway); and (5) their innervation by a single, wide-field contralateral tangential neuron from the central brain. Progenitors of both also express the gene atonal early in their proliferation from the inner anlage of the developing optic lobe, being alone among many other cell type progeny to do so. Yet T4 receives input in the second neuropil, or medulla (ME), and T5 in the third neuropil or lobula (LO). Here we suggest that these two cell types were originally one, that their ancestral cell population duplicated and split to innervate separate ME and LO neuropils, and that a fiber crossing-the internal chiasma-arose between the two neuropils. The split most plausibly occurred, we suggest, with the formation of the LO as a new neuropil that formed when it separated from its ancestral neuropil to leave the ME, suggesting additionally that ME input neurons to T4 and T5 may also have had a common origin.

Published

2015

42. The irre cell recognition module (IRM) protein Kirre is required to form the reciprocal synaptic network of L4 neurons in the Drosophila lamina.

Author

Lüthy K, Ahrens B, Rawal S, Lu Z, Tarnogorska D, Meinertzhagen IA, and Fischbach KF

Subjects

Animals, Animals, Genetically Modified, Drosophila, Drosophila Proteins genetics, Membrane Proteins genetics, Muscle Proteins genetics, Nerve Net cytology, Neurons cytology, Optic Lobe, Nonmammalian cytology, Drosophila Proteins metabolism, Membrane Proteins metabolism, Muscle Proteins metabolism, Nerve Net metabolism, Neurons metabolism, Optic Lobe, Nonmammalian metabolism, Synapses metabolism

Abstract

Each neuropil module, or cartridge, in the fly's lamina has a fixed complement of cells. Of five types of monopolar cell interneurons, only L4 has collaterals that invade neighboring cartridges. In the proximal lamina, these collaterals form reciprocal synapses with both the L2 of their own cartridge and the L4 collateral branches from two other neighboring cartridges. During synaptogenesis, L4 collaterals strongly express the cell adhesion protein Kirre, a member of the irre cell recognition module (IRM) group of proteins ( Fischbach et al., 2009 , J Neurogenet, 23, 48-67). The authors show by mutant analysis and gene knockdown techniques that L4 neurons develop their lamina collaterals in the absence of this cell adhesion protein. Using electron microscopy (EM), the authors demonstrate, however, that without Kirre protein these L4 collaterals selectively form fewer synapses. The collaterals of L4 neurons of various genotypes reconstructed from serial-section EM revealed that the number of postsynaptic sites was dramatically reduced in the absence of Kirre, almost eliminating any synaptic input to L4 neurons. A significant reduction of presynaptic sites was also detected in kirre(0) mutants and gene knockdown flies using RNA interference. L4 neuron reciprocal synapses are thus almost eliminated. A presynaptic marker, Brp-short(GFP) confirmed these data using confocal microscopy. This study reveals that removing Kirre protein specifically disrupts the functional L4 synaptic network in the Drosophila lamina.

Published

2014

43. Differential adhesion determines the organization of synaptic fascicles in the Drosophila visual system.

Author

Schwabe T, Borycz JA, Meinertzhagen IA, and Clandinin TR

Subjects

Animals, Cadherins metabolism, Drosophila Proteins metabolism, Drosophila melanogaster genetics, Drosophila melanogaster growth & development, Larva growth & development, Larva physiology, Neurites metabolism, Photoreceptor Cells, Invertebrate physiology, Pupa growth & development, Pupa physiology, Synapses physiology, Visual Pathways growth & development, Visual Pathways physiology, Cadherins genetics, Drosophila Proteins genetics, Drosophila melanogaster physiology, Photoreceptor Cells, Invertebrate cytology

Abstract

Background: Neuronal circuits in worms, flies, and mammals are organized so as to minimize wiring length for a functional number of synaptic connections, a phenomenon called wiring optimization. However, the molecular mechanisms that establish optimal wiring during development are unknown. We addressed this question by studying the role of N-cadherin in the development of optimally wired neurite fascicles in the peripheral visual system of Drosophila., Results: Photoreceptor axons surround the dendrites of their postsynaptic targets, called lamina cells, within a concentric fascicle called a cartridge. N-cadherin is expressed at higher levels in lamina cells than in photoreceptors, and all genetic manipulations that invert these relative differences displace lamina cells to the periphery and relocate photoreceptor axon terminals into the center., Conclusions: Differential expression of a single cadherin is both necessary and sufficient to determine cartridge structure because it positions the most-adhesive elements that make the most synapses at the core and the less-adhesive elements that make fewer synapses at the periphery. These results suggest a general model by which differential adhesion can be utilized to determine the relative positions of axons and dendrites to establish optimal wiring., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

44. Candidate neural substrates for off-edge motion detection in Drosophila.

Author

Shinomiya K, Karuppudurai T, Lin TY, Lu Z, Lee CH, and Meinertzhagen IA

Subjects

Animals, Microscopy, Electron, Neurons physiology, Visual Pathways, Drosophila melanogaster physiology, Motion Perception

Abstract

Background: In the fly's visual motion pathways, two cell types-T4 and T5-are the first known relay neurons to signal small-field direction-selective motion responses [1]. These cells then feed into large tangential cells that signal wide-field motion. Recent studies have identified two types of columnar neurons in the second neuropil, or medulla, that relay input to T4 from L1, the ON-channel neuron in the first neuropil, or lamina, thus providing a candidate substrate for the elementary motion detector (EMD) [2]. Interneurons relaying the OFF channel from L1's partner, L2, to T5 are so far not known, however., Results: Here we report that multiple types of transmedulla (Tm) neurons provide unexpectedly complex inputs to T5 at their terminals in the third neuropil, or lobula. From the L2 pathway, single-column input comes from Tm1 and Tm2 and multiple-column input from Tm4 cells. Additional input to T5 comes from Tm9, the medulla target of a third lamina interneuron, L3, providing a candidate substrate for L3's combinatorial action with L2 [3]. Most numerous, Tm2 and Tm9's input synapses are spatially segregated on T5's dendritic arbor, providing candidate anatomical substrates for the two arms of a T5 EMD circuit; Tm1 and Tm2 provide a second. Transcript profiling indicates that T5 expresses both nicotinic and muscarinic cholinoceptors, qualifying T5 to receive cholinergic inputs from Tm9 and Tm2, which both express choline acetyltransferase (ChAT)., Conclusions: We hypothesize that T5 computes small-field motion signals by integrating multiple cholinergic Tm inputs using nicotinic and muscarinic cholinoceptors., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

45. Slowly contracting muscles power the rapid jumping of planthopper insects (Hemiptera, Issidae).

Author

Burrows M, Meinertzhagen IA, and Bräunig P

Subjects

Animals, Hemiptera ultrastructure, Movement, Muscle Contraction, Muscle Fibers, Skeletal physiology, Muscle Fibers, Skeletal ultrastructure, Hemiptera anatomy & histology, Hemiptera physiology

Abstract

The planthopper insect Issus produces one of the fastest and most powerful jumps of any insect. The jump is powered by large muscles that are found in its thorax and that, in other insects, contribute to both flying and walking movements. These muscles were therefore analysed by transmission electron microscopy to determine whether they have the properties of fast-acting muscle used in flying or those of more slowly acting muscle used in walking. The muscle fibres are arranged in a parallel bundle that inserts onto an umbrella-shaped tendon. The individual fibres have a diameter of about 70 μm and are subdivided into myofibrils a few micrometres in diameter. No variation in ultrastructure was observed in various fibres taken from different parts of the muscle. The sarcomeres are about 15 μm long and the A bands about 10 μm long. The Z lines are poorly aligned within a myofibril. Mitochondrial profiles are sparse and are close to the Z lines. Each thick filament is surrounded by 10-12 thin filaments and the registration of these arrays of filaments is irregular. Synaptic boutons from the two excitatory motor neurons to the muscle fibres are characterised by accumulations of ~60 translucent 40-nm-diameter vesicle profiles per section, corresponding to an estimated 220 vesicles, within a 0.5-μm hemisphere at a presynaptic density. All ultrastructural features conform to those of slow muscle and thus suggest that the muscle is capable of slow sustained contractions in keeping with its known actions during jumping. A fast and powerful movement is thus generated by a slow muscle.

Published

2014

46. Charcot-Marie-Tooth 2B mutations in rab7 cause dosage-dependent neurodegeneration due to partial loss of function.

Author

Cherry S, Jin EJ, Ozel MN, Lu Z, Agi E, Wang D, Jung WH, Epstein D, Meinertzhagen IA, Chan CC, and Hiesinger PR

Subjects

Animals, Base Sequence, Disease Models, Animal, Drosophila, Guanosine Diphosphate metabolism, Guanosine Triphosphate metabolism, Laminopathies, Molecular Sequence Data, Sensory Receptor Cells metabolism, Sequence Homology, Nucleic Acid, rab GTP-Binding Proteins chemistry, rab7 GTP-Binding Proteins, Charcot-Marie-Tooth Disease genetics, Mutation, Neurodegenerative Diseases genetics, rab GTP-Binding Proteins genetics

Abstract

The small GTPase Rab7 is a key regulator of endosomal maturation in eukaryotic cells. Mutations in rab7 are thought to cause the dominant neuropathy Charcot-Marie-Tooth 2B (CMT2B) by a gain-of-function mechanism. Here we show that loss of rab7, but not overexpression of rab7 CMT2B mutants, causes adult-onset neurodegeneration in a Drosophila model. All CMT2B mutant proteins retain 10-50% function based on quantitative imaging, electrophysiology, and rescue experiments in sensory and motor neurons in vivo. Consequently, expression of CMT2B mutants at levels between 0.5 and 10-fold their endogenous levels fully rescues the neuropathy-like phenotypes of the rab7 mutant. Live imaging reveals that CMT2B proteins are inefficiently recruited to endosomes, but do not impair endosomal maturation. These findings are not consistent with a gain-of-function mechanism. Instead, they indicate a dosage-dependent sensitivity of neurons to rab7-dependent degradation. Our results suggest a therapeutic approach opposite to the currently proposed reduction of mutant protein function. DOI: http://dx.doi.org/10.7554/eLife.01064.001.

Published

2013

47. A visual motion detection circuit suggested by Drosophila connectomics.

Author

Takemura SY, Bharioke A, Lu Z, Nern A, Vitaladevuni S, Rivlin PK, Katz WT, Olbris DJ, Plaza SM, Winston P, Zhao T, Horne JA, Fetter RD, Takemura S, Blazek K, Chang LA, Ogundeyi O, Saunders MA, Shapiro V, Sigmund C, Rubin GM, Scheffer LK, Meinertzhagen IA, and Chklovskii DB

Subjects

Animals, Female, Visual Pathways cytology, Connectome, Drosophila physiology, Models, Biological, Motion Perception physiology, Visual Pathways physiology

Abstract

Animal behaviour arises from computations in neuronal circuits, but our understanding of these computations has been frustrated by the lack of detailed synaptic connection maps, or connectomes. For example, despite intensive investigations over half a century, the neuronal implementation of local motion detection in the insect visual system remains elusive. Here we develop a semi-automated pipeline using electron microscopy to reconstruct a connectome, containing 379 neurons and 8,637 chemical synaptic contacts, within the Drosophila optic medulla. By matching reconstructed neurons to examples from light microscopy, we assigned neurons to cell types and assembled a connectome of the repeating module of the medulla. Within this module, we identified cell types constituting a motion detection circuit, and showed that the connections onto individual motion-sensitive neurons in this circuit were consistent with their direction selectivity. Our results identify cellular targets for future functional investigations, and demonstrate that connectomes can provide key insights into neuronal computations.

Published

2013

48. An endocrine disruptor, bisphenol A, affects development in the protochordate Ciona intestinalis: hatching rates and swimming behavior alter in a dose-dependent manner.

Author

Matsushima A, Ryan K, Shimohigashi Y, and Meinertzhagen IA

Subjects

Animals, Ciona intestinalis embryology, Dose-Response Relationship, Drug, Embryo, Nonmammalian drug effects, Swimming, Behavior, Animal drug effects, Benzhydryl Compounds toxicity, Embryonic Development drug effects, Endocrine Disruptors toxicity, Phenols toxicity, Water Pollutants, Chemical toxicity

Abstract

Bisphenol A (BPA) is widely used industrially to produce polycarbonate plastics and epoxy resins. Numerous studies document the harmful effects caused by low-dose BPA exposure especially on nervous systems and behavior in experimental animals such as mice and rats. Here, we exposed embryos of a model chordate, Ciona intestinalis, to seawater containing BPA to evaluate adverse effects on embryonic development and on the swimming behavior of subsequent larvae. Ciona is ideal because its larva develops rapidly and has few cells. The rate of larval hatching decreased in a dose-dependent manner with exposures to BPA above 3 μM; swimming behavior was also affected in larvae emerging from embryos exposed to 1 μM BPA. Adverse effects were most severe on fertilized eggs exposed to BPA within 7 h post-fertilization. Ciona shares twelve nuclear receptors with mammals, and BPA is proposed to disturb the physiological functions of one or more of these., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2013

49. Age-related plasticity in the synaptic ultrastructure of neurons in the mushroom body calyx of the adult honeybee Apis mellifera.

Author

Groh C, Lu Z, Meinertzhagen IA, and Rössler W

Subjects

Animals, Bees growth & development, Female, Mushroom Bodies growth & development, Neurons physiology, Synapses physiology, Aging physiology, Bees ultrastructure, Mushroom Bodies ultrastructure, Neuronal Plasticity physiology, Neurons ultrastructure, Synapses ultrastructure

Abstract

The mushroom bodies are high-order sensory integration centers in the insect brain. In the honeybee, their main sensory input regions are large, doubled calyces with modality-specific, distinct sensory neuropil regions. We investigated adult structural plasticity of input synapses in the microglomeruli of the olfactory lip and visual collar. Synapsin-immunolabeled whole-mount brains reveal that during the natural transition from nursing to foraging, a significant volume increase in the calycal subdivisions is accompanied by a decreased packing density of boutons from input projection neurons. To investigate the associated ultrastructural changes at pre- and postsynaptic sites of individual microglomeruli, we employed serial-section electron microscopy. In general, the membrane surface area of olfactory and visual projection neuron boutons increased significantly between 1-day-old bees and foragers. Both types of boutons formed ribbon and non-ribbon synapses. The percentage of ribbon synapses per bouton was significantly increased in the forager. At each presynaptic site the numbers of postsynaptic partners-mostly Kenyon cell dendrites-likewise increased. Ribbon as well as non-ribbon synapses formed mainly dyads in the 1-day-old bee, and triads in the forager. In the visual collar, outgrowing Kenyon cell dendrites form about 140 contacts upon a projection neuron bouton in the forager compared with only about 95 in the 1-day-old bee, resulting in an increased divergence ratio between the two stages. This difference suggests that synaptic changes in calycal microcircuits of the mushroom body during periods of altered sensory activity and experience promote behavioral plasticity underlying polyethism and social organization in honeybee colonies., (Copyright © 2012 Wiley Periodicals, Inc.)

Published

2012

50. A final hooroo to John Edwards, BSc, MSc (Auckland), PhD (Cantab) 1931-2012.

Author

Meinertzhagen IA

Subjects

Animals, History, 20th Century, History, 21st Century, New Zealand, United States, Entomology history, Neurosciences history, Periodicals as Topic history, Physiology, Comparative history

Published

2012