The neuronal architecture of the mushroom body provides a logic for associative learning

Aso, Yoshinori; Hattori, Daisuke; Yu, Yongmei; Johnston, Rebecca M.; Iyer, Nirmala; Ngo, Teri T.B.; Dionne, Heather; Abbott, L. F.; Axel, Richard; Tanimoto, Hiromu; Rubin, Gerald M.

doi:10.7554/elife.04577

Cited by 912 publications

(1,819 citation statements)

References 115 publications

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“…We have used those lines here and they have also been used in other brain regions (35,36). However, the MCFO reagents can also be readily incorporated into more complex genetic schemes.…”

Section: Mcfo Facilitates Visualization Of Complex Arrangements Of Nementioning

confidence: 99%

Optimized tools for multicolor stochastic labeling reveal diverse stereotyped cell arrangements in the fly visual system

Nern

Pfeiffer

Rubin

2015

Proc. Natl. Acad. Sci. U.S.A.

517

691

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We describe the development and application of methods for high-throughput neuroanatomy in Drosophila using light microscopy. These tools enable efficient multicolor stochastic labeling of neurons at both low and high densities. Expression of multiple membrane-targeted and distinct epitope-tagged proteins is controlled both by a transcriptional driver and by stochastic, recombinase-mediated excision of transcription-terminating cassettes. This MultiColor FlpOut (MCFO) approach can be used to reveal cell shapes and relative cell positions and to track the progeny of precursor cells through development. Using two different recombinases, the number of cells labeled and the number of color combinations observed in those cells can be controlled separately. We demonstrate the utility of MCFO in a detailed study of diversity and variability of Distal medulla (Dm) neurons, multicolumnar local interneurons in the adult visual system. Similar to many brain regions, the medulla has a repetitive columnar structure that supports parallel information processing together with orthogonal layers of cell processes that enable communication between columns. We find that, within a medulla layer, processes of the cells of a given Dm neuron type form distinct patterns that reflect both the morphology of individual cells and the relative positions of their arbors. These stereotyped cell arrangements differ between cell types and can even differ for the processes of the same cell type in different medulla layers. This unexpected diversity of coverage patterns provides multiple independent ways of integrating visual information across the retinotopic columns and implies the existence of multiple developmental mechanisms that generate these distinct patterns.neuroanatomy | Drosophila | interneuron diversity | light microscopy | recombinase N ervous systems contain numerous and diverse cells displaying complex anatomical relationships. The specification and patterning of these cells must be generated by the execution of a much smaller set of instructions encoded in the genome. How many different genetic algorithms are needed? How precise are their outcomes? What types of rules do they follow? Answering such questions requires knowledge of the anatomy of neuronal processes for many different cell types, for numerous cells of the same type, and in multiple individuals. We describe here the development of a set of methods for collecting such data by light microscopy and their application in the adult visual system of Drosophila.Neuronal morphology is often sufficiently stereotyped to identify cell types. For example, many cell populations in vertebrate and invertebrate visual systems can be reliably distinguished on the basis of cell shape (1-3). In at least some cases, these anatomical cell types have been shown to correlate well with classifications based on genetic marker expression or functional properties. Important anatomical features are not limited to cell shape, but also include the spatial relationships between cells. One critical ...

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“…We have used those lines here and they have also been used in other brain regions (35,36). However, the MCFO reagents can also be readily incorporated into more complex genetic schemes.…”

Section: Mcfo Facilitates Visualization Of Complex Arrangements Of Nementioning

confidence: 99%

Optimized tools for multicolor stochastic labeling reveal diverse stereotyped cell arrangements in the fly visual system

Nern

Pfeiffer

Rubin

2015

Proc. Natl. Acad. Sci. U.S.A.

517

691

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“…In the earlier sections, I assumed three things: (i) all Kenyon cells have six claws, (ii) all Kenyon cells are interchangeable and sample all glomeruli with the same probability, and (iii) all synapses made by projection neurons onto Kenyon cells have the same strength. In fact, the number of Kenyon cell claws ranges from around 1 to 11 (16), three classes of Kenyon cells with different properties and different targets for their axons are known (14,30), and the synaptic strength varies considerably from one synapse to the next (28), whereas I used the mean value. Relaxing these simplifying assumptions changes my results quantitatively, but does not alter the main conclusions.…”

Section: A Distributed Representation Of Olfactory Information In Thementioning

confidence: 99%

“…The mushroom body (13,14) is a large (for the fly brain) structure with a neuropil calyx that contains the dendrites of many intrinsic neurons, the Kenyon cells (the Kenyon cell bodies are grouped just next to the calyx), and with two elongated lobes, one vertical and one horizontal, to which Kenyon cell axons project. The Kenyon cells and their associated circuitry constitute the second stage of the Marr motif (corresponding to the cerebellar granule cells), and the lobes contain the third stage (corresponding to the cerebellar Purkinje cells) of the three-stage architecture.…”

Section: Will Consider (Seementioning

confidence: 99%

What the fly’s nose tells the fly’s brain

Stevens

2015

Proc. Natl. Acad. Sci. U.S.A.

102

134

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The fly olfactory system has a three-layer architecture: The fly’s olfactory receptor neurons send odor information to the first layer (the encoder) where this information is formatted as combinatorial odor code, one which is maximally informative, with the most informative neurons firing fastest. This first layer then sends the encoded odor information to the second layer (decoder), which consists of about 2,000 neurons that receive the odor information and “break” the code. For each odor, the amplitude of the synaptic odor input to the 2,000 second-layer neurons is approximately normally distributed across the population, which means that only a very small fraction of neurons receive a large input. Each odor, however, activates its own population of large-input neurons and so a small subset of the 2,000 neurons serves as a unique tag for the odor. Strong inhibition prevents most of the second-stage neurons from firing spikes, and therefore spikes from only the small population of large-input neurons is relayed to the third stage. This selected population provides the third stage (the user) with an odor label that can be used to direct behavior based on what odor is present.

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“…Each glomerulus in the AL receives exclusive input from OSNs expressing a single odorant receptor. Second-order projection neurons (PN) typically innervate single glomeruli and link the AL to higher-order olfactory centers in the lateral horn (for innate behaviors) and the mushroom body (for learned behaviors) (Jefferis et al 2007;Aso et al 2014). Similar to (Hernandez-Nunez et al 2015), (Bell and Wilson 2016) asked how glomerular activation is translated into walking behavior to odors (odortaxis).…”

Section: Linking Neural Responses With Behavior -Neuronal Decoding Momentioning

confidence: 99%

The use of computational modeling to link sensory processing with behavior in Drosophila

Clemens

Murthy

2017

Preprint

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A major goal of systems neuroscience is to understand how the brain represents information, and how those representations are used to drive behavior. Even though genetic model organisms like Drosophila grant unprecedented experimental access to the nervous system for manipulating and recording neural activity, the complexity of natural stimuli and natural behaviors still poses a challenge for solving the connections between neural activity and behavior. Here, we advocate for the use of computational modeling to complement (and enhance) the Drosophila toolkit. We first lay out a modelling framework for making sense of the relation between natural sensory stimuli, neuronal responses, and natural behavior. We then highlight how this framework can be used to reveal how neural circuits drive behavior, using selected case studies.PeerJ Preprints | https://doi.org/10.7287/peerj.preprints.2720v1 | CC BY 4.0 Open Access |

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The neuronal architecture of the mushroom body provides a logic for associative learning

Cited by 912 publications

References 115 publications

Optimized tools for multicolor stochastic labeling reveal diverse stereotyped cell arrangements in the fly visual system

Optimized tools for multicolor stochastic labeling reveal diverse stereotyped cell arrangements in the fly visual system

What the fly’s nose tells the fly’s brain

The use of computational modeling to link sensory processing with behavior in Drosophila

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