Sun Navigation Requires Compass Neurons in Drosophila

Giraldo, Ysabel Milton; Leitch, Katherine J.; Ros, Ivo G.; Warren, Timothy L.; Weir, Peter; Dickinson, Michael H.

doi:10.1016/j.cub.2018.07.002

Cited by 136 publications

(194 citation statements)

References 51 publications

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“…Neurons of the CX, notably the E-PG cells, have been shown to encode heading, an important idiothetic feature for path integration, while walking (Green et al, 2017;Seelig and Jayaraman, 2015;Turner-Evans et al, 2017) and in flight (Giraldo et al, 2018) and appear to contribute to ring attractor dynamics (Su 2017, Kakaria 2017). The position of the bump of activity in E-PGs that encodes heading can be updated with or without visual feedback, and we hypothesized they could be involved in LDM.…”

Section: Discussionmentioning

confidence: 99%

“…As a fly turns, a spatially localized "bump" of neural activity moves through this structure to encode the heading estimate. Both visual and non-visual inputs could update this heading representation, and when the animal was not moving, the bump remains in one place via apparent ring-attractor functionality (Giraldo et al, 2018;Green et al, 2017;Kakaria and de Bivort, 2017;Seelig and Jayaraman, 2015). In addition to representing features useful for orientated walking behaviors, representations in the CX show context-dependence based on an animal's state of activity (Martin et al, 2015;Weir et al, 2013), and neurons in the CX can causally modulate internal state (Donlea et al, 2018;Liu et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

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A neural circuit basis for context-modulation of individual locomotor behavior

Skutt-Kakaria

Reimers

Currier

et al. 2019

Preprint

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Defying the cliche that biological variation arises from differences in nature or nurture, genetically identical animals reared in the same environment exhibit striking differences in their behaviors. Innate behaviors can be surprisingly flexible, for example by exhibiting context-dependence. The intersection of behavioral individuality and contextdependence is largely unexplored, particularly at the neural circuit level. Here, we show that individual flies' tendencies to turn left or right (locomotor handedness) changes when ambient illumination changes. This change is itself a stable individual behavioral characteristic. Silencing output neurons of the central complex (a premotor area that mediates goal-directed navigation) blocks this change. These neurons respond to light with idiosyncratic changes to their baseline calcium levels, and idiosyncratic morphological variation in their presynaptic arbors correlates with idiosyncratic sensory-context-specific turn biases. These findings provide a circuit mechanism by which individual locomotor biases arise and are modulated by sensory context.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A neural circuit basis for context-modulation of individual locomotor behavior

Skutt-Kakaria

Reimers

Currier

et al. 2019

Preprint

View full text Add to dashboard Cite

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“…Catch-and-release experiments from a fixed point in the desert suggested that Drosophila (melanogaster and pseudoobscura) disperse into all directions equally and are able to keep straight headings over extended periods of time, while flying in environments which provide few visual landmarks 20,21 . For a better quantitative understanding of the mechanisms underlying such processes, skylight navigation experiments using virtual flight arenas therefore serve as an attractive platform for the study of the navigation skills of wild type insects, thereby providing the platform for testing transgenic specimens harboring well-defined circuit perturbations 22,23 .…”

Section: Introductionmentioning

confidence: 99%

Heading choices of flyingDrosophilaunder changing angles of polarized light

Mathejczyk

Wernet

2019

Preprint

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2 Summary Many navigating insects include the celestial polarization pattern as an additional visual cue to orient their travels. Spontaneous orientation responses of both walking and flying fruit flies (Drosophila melanogaster) to linearly polarized light have previously been demonstrated. Using newly designed modular flight arenas consisting entirely of off-theshelf parts and 3D-printed components we present individual flying flies with a slow and continuous rotational change in the incident angle of linear polarization. Under such openloop conditions, single flies choose arbitrary headings with respect to the angle of polarized light and show a clear tendency to maintain those chosen headings for several minutes, thereby adjusting their course to the slow rotation of the incident stimulus. Importantly, flies show the tendency to maintain a chosen heading even when two individual test periods under a linearly polarized stimulus are interrupted by an epoch of unpolarized light lasting several minutes. Finally, we show that these behavioral responses are wavelength-specific, existing under polarized UV stimulus while being absent under polarized green light. Taken together, these findings provide further evidence supporting Drosophila's abilities to use celestial cues for visually guided navigation and course correction.

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“…First established using larger insects, these assays have become particular useful in the dissection of visual circuitry in Drosophila melanogaster, by taking advantage of its unique molecular genetic toolkit 1 . Since early adaptations to Drosophila 4,5 , virtual flight arenas have been used to quantify behavioral responses to a multitude of visual stimuli, ranging (for example) from moving edges, different colors, celestial bodies, learned shapes, to more complex visual scenes [6][7][8][9][10][11][12] . Visual responses of flying Drosophila melanogaster to linearly polarized light emanating from above (thereby simulating the celestial polarization pattern) using a flight simulator have also been demonstrated [13][14][15] .…”

Section: Introductionmentioning

confidence: 99%

New modular assays for the quantitative study of skylight navigation in flying flies

Mathejczyk

2019

Preprint

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The quantitative study of behavioral responses provides crucial information about how neural circuits process visual information, thereby revealing the computations responsible for shaping the animal's perception of the outside world. Over the last decade, insects have served as particularly powerful model systems, either when walking on air suspended balls (spherical treadmill), or when flying while glued to a needle (virtual flight arena). The use of virtual flight arenas is complicated by the fact that an effective experimental setup needs to combine a rather complex set of custom-built mechanical, electronic, and software components. Assembling such an apparatus amounts to a major challenge when working in an environment without the support of a machine shop. Here we present detailed instructions for the assembly of virtual flight arenas optimized for Drosophila skylight navigation, which can easily be modified towards other uses. This system consists entirely of off-the-shelf parts and 3D-printed components, combining a modular flight arena designed to reduce visual artifacts, swappable high-power LED light sources, polarization filters on a computer-controlled rotating filter wheel, all placed within a temperature and humidity controlled environment. Taken together, these findings demonstrate the usefulness of these assays for the study of skylight navigation in flies.

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Sun Navigation Requires Compass Neurons in Drosophila

Cited by 136 publications

References 51 publications

A neural circuit basis for context-modulation of individual locomotor behavior

A neural circuit basis for context-modulation of individual locomotor behavior

Heading choices of flyingDrosophilaunder changing angles of polarized light

New modular assays for the quantitative study of skylight navigation in flying flies

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