Neuroarchitecture and neuroanatomy of the <i>Drosophila</i> central complex: A GAL4‐based dissection of protocerebral bridge neurons and circuits

Wolff, Tanya; Iyer, Nirmala; Rubin, Gerald M.

doi:10.1002/cne.23705

Cited by 269 publications

(628 citation statements)

References 54 publications

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“…This issue was resolved by changing the parameter Th DP from 0.01 to 0.001. To validate the performance of the new classifier, we selected the 442 neurons that were reported in Lin et al 2013 (Lin et al 2013) as test neurons because their polarity has been reported in detail by two studies (Lin et al 2013;Wolff, Iyer, and Rubin 2015). We removed the EIP neuron class, which innervates the ellipsoid body, inferior dorsofrontal protocerebrum, and protocerebral bridge, because the reported polarity is inconsistent between the two studies.…”

Section: Synapse Polarity Prediction and Validationmentioning

confidence: 99%

“…Based on Lin et al 2013 (Lin et al 2013) and Wolff et al 2015(Wolff, Iyer, andRubin 2015), who reported the anatomy of the same circuits, we were able to derive the network connections of these neurons and use them as a reference to optimize our connection estimation protocol. Lin et al 2013 (Lin et al 2013) and Wolff et al 2015(Wolff, Iyer, andRubin 2015) reported the polarity and innervated subregions of each neuron. To construct the reference connectivity of these neurons, we assumed that a neuron that projects its axonal arbor to a glomerulus forms synapses with another neuron that has its dendritic arbor in the same glomerulus.…”

Section: ∑ ܰmentioning

confidence: 99%

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A single-cell level and connectome-derived computational model of the Drosophila brain

Huang

Wang

et al. 2018

Preprint

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Computer simulations play an important role in testing hypotheses, integrating knowledge, and providing predictions of neural circuit functions. While considerable effort has been dedicated into simulating primate or rodent brains, the fruit fly (Drosophila melanogaster) is becoming a promising model animal in computational neuroscience for its small brain size, complex cognitive behavior, and abundancy of data available from genes to circuits.Moreover, several Drosophila connectome projects have generated a large number of neuronal images that account for a significant portion of the brain, making a systematic investigation of the whole brain circuit possible. Supported by FlyCircuit (http://www.flycircuit.tw), one of the largest Drosophila neuron image databases, we began a long-term project with the goal to construct a whole-brain spiking network model of the Drosophila brain. In this paper, we report the outcome of the first phase of the project. We developed the Flysim platform, which 1) identifies the polarity of each neuron arbor, 2) predicts connections between neurons, 3) translates morphology data from the database into physiology parameters for computational modeling, 4) reconstructs a brain-wide network model, which consists of 20,089 neurons and 1,044,020 synapses, and 5) performs computer simulations of the resting state. We compared the reconstructed brain network with a randomized brain network by shuffling the connections of each neuron. We found that the reconstructed brain can be easily stabilized by implementing synaptic short-term depression, while the randomized one exhibited seizure-like firing activity under the same treatment.Furthermore, the reconstructed Drosophila brain was structurally and dynamically more diverse than the randomized one and exhibited both Poisson-like and patterned firing activities. Despite being at its early stage of development, this single-cell level brain model allows us to study some of the fundamental properties of neural networks including network balance, critical behavior, long-term stability, and plasticity.All rights reserved. No reuse allowed without permission.(which was not peer-reviewed) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity.

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Section: Synapse Polarity Prediction and Validationmentioning

confidence: 99%

Section: ∑ ܰmentioning

confidence: 99%

A single-cell level and connectome-derived computational model of the Drosophila brain

Huang

Wang

et al. 2018

Preprint

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“…The various modules - protocerebral bridge (PB), fan-shaped body (FB; or upper division of the central body), ellipsoid body (EB; or lower division of the central body), noduli (N) and lateral accessory lobes (LAL) (see Strausfeld 2012; Ito et al 2014; Wolff et al 2015) - subserve a range of functions including spatial orientation and memory (Liu et al 2006; Neuser et al 2008; Pan et al 2009), as well as sensory integration for motor control (Ilius et al 1994; Strauss 2002; Heinze and Homberg 2007; Harley and Ritzmann 2010; Strausfeld and Hirth 2013). …”

Section: Introductionmentioning

confidence: 99%

“…Developmental studies have revealed that the intricate columnar wiring of the fan-shaped body is established quite rapidly, but at stages which also vary with the lifestyle of the insect. In the grasshopper, it develops fully during embryogenesis (Boyan et al 2008b, 2015), while in flies, it happens during pupal stages (Renn et al 1999; Young and Armstrong 2010; Lovick et al, 2013; Riebli et al 2013; Wolff et al 2015; Lovick et al, 2017). The columnar neuroarchitecture itself is generated by a sophisticated mechanism of axogenesis known as “fascicle switching” in which a subset of W-Z axons of the embryonic grasshopper (Boyan et al 2008b) and larval Drosophila (Young and Armstrong 2010; Riebli et al 2013) brain decussates at stereotypic locations along the brain commissure, resulting in a discrete set of fiber bundles oriented orthogonally to the commissure.…”

Section: Introductionmentioning

confidence: 99%

“…The columnar neuroarchitecture itself is generated by a sophisticated mechanism of axogenesis known as “fascicle switching” in which a subset of W-Z axons of the embryonic grasshopper (Boyan et al 2008b) and larval Drosophila (Young and Armstrong 2010; Riebli et al 2013) brain decussates at stereotypic locations along the brain commissure, resulting in a discrete set of fiber bundles oriented orthogonally to the commissure. The decussating W-Z axons belong to the so-called columnar neurons which interconnect the modules of the central complex (i.e., protocerebral bridge, fan-shaped and ellipsoid bodies, noduli; see Heinze and Homberg 2008; Pfeiffer and Homberg 2014; Wolff et al 2015). Comparative analyses suggest that the number of columns in a given species may relate to the number of lineages participating (see Strausfeld 2012) and that the mechanism is conserved throughout the Panarthropoda (Loesel et al 2002; Boyan et al 2015).…”

Section: Introductionmentioning

confidence: 99%

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A conserved plan for wiring up the fan-shaped body in the grasshopper and Drosophila

et al. 2017

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The central complex comprises an elaborate system of modular neuropils which mediate spatial orientation and sensory-motor integration in insects such as the grasshopper and Drosophila. The neuroarchitecture of the largest of these modules, the fan-shaped body, is characterized by its stereotypic set of decussating fiber bundles. These are generated during development by axons from four homologous protocerebral lineages which enter the commissural system and subsequently decussate at stereotypic locations across the brain midline. Since the commissural organization prior to fan-shaped body formation has not been previously analysed in either species, it was not clear how the decussating bundles relate to individual lineages, or if the projection pattern is conserved across species. In this study, we trace the axonal projections from the homologous central complex lineages into the commissural system of the embryonic and larval brains of both the grasshopper and Drosophila. Projections into the primordial commissures of both species are found to be lineage-specific and allow putatively equivalent fascicles to be identified. Comparison of the projection pattern before and after the commencement of axon decussation in both species reveals that equivalent commissural fascicles are involved in generating the columnar neuroarchitecture of the fan-shaped body. Further, the tract-specific columns in both the grasshopper and Drosophila can be shown to contain axons from identical combinations of central complex lineages, suggesting that this columnar neuroarchitecture is also conserved.

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Topographic organization and possible function of the posterior optic tubercles in the brain of the desert locust Schistocerca gregaria

Beetz

Jundi

Heinze

et al. 2015

J of Comparative Neurology

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Migrating desert locusts, Schistocerca gregaria, are able to use the skylight polarization pattern for navigation. They detect polarized light with a specialized dorsal rim area in their compound eye. After multistage processing, polarization signals are transferred to the central complex, a midline-spanning brain area involved in locomotor control. Polarization-sensitive tangential neurons (TB-neurons) of the protocerebral bridge, a part of the central complex, give rise to a topographic arrangement of preferred polarization angles in the bridge, suggesting that the central complex acts as an internal sky compass. TB-neurons connect the protocerebral bridge with two adjacent brain areas, the posterior optic tubercles. To analyze the polarotopic organization of the central complex further, we investigated the number and morphologies of TB-neurons and the presence and colocalization of three neuroactive substances in these neurons. Triple immunostaining with antisera against Diploptera punctata allatostatin (Dip-AST), Manduca sexta allatotropin (Mas-AT), and serotonin (5HT) raised in the same host species revealed three spatially distinct TB-neuron clusters, each consisting of 10 neurons per hemisphere: cluster 1 and 3 showed Dip-AST/5HT immunostaining, whereas cluster 2 showed Dip-AST/Mas-AT immunostaining. Five subtypes of TB-neuron could be distinguished based on ramification patterns. Corresponding to ramification domains in the protocerebral bridge, the neurons invaded distinct but overlapping layers within the posterior optic tubercle. Similarly, neurons interconnecting the tubercles of the two hemispheres also targeted distinct layers of these neuropils. From these data we propose a neuronal circuit that may be suited to stabilize the internal sky compass in the central complex of the locust.

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Neuroarchitecture and neuroanatomy of the Drosophila central complex: A GAL4‐based dissection of protocerebral bridge neurons and circuits

Cited by 269 publications

References 54 publications

A single-cell level and connectome-derived computational model of the Drosophila brain

A single-cell level and connectome-derived computational model of the Drosophila brain

A conserved plan for wiring up the fan-shaped body in the grasshopper and Drosophila

Topographic organization and possible function of the posterior optic tubercles in the brain of the desert locust Schistocerca gregaria

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