Asynchronous haltere input drives specific wing and head movements in Drosophila
Description
Halteres are multifunctional mechanosensory organs unique to the true flies (Diptera). A set of reduced hindwings, the halteres beat at the same frequency as the lift-generating forewings and sense inertial forces via mechanosensory campaniform sensilla. Though haltere ablation makes stable flight impossible, the specific role of wing-synchronous input has not been established. Using small iron filings attached to the halteres of tethered flies and an alternating electromagnetic field, we experimentally decoupled the wings and halteres of flying Drosophila and observed the resulting changes in wingbeat amplitude and head orientation. We find that asynchronous haltere input results in fast amplitude changes in the wing ("wing hitches"), but does not appreciably move the head. In multi-modal experiments, we find that wing and gaze optomotor responses are disrupted differently by asynchronous input. These effects of wing-asynchronous haltere input suggest that specific sensory information is necessary for maintaining wing amplitude stability and adaptive gaze control.
Notes
Dataset includes extracted kinematic timeseries in *.mat format, which is readable by MATLAB and the freely-available OCTAVE software (https://www.gnu.org/software/octave/index). Included README files provide details about fields in each data file
Included analysis scripts were written with MATLAB 2021b and should function with this and subsequent versions.
Funding provided by: United States Air Force Office of Scientific Research
Crossref Funder Registry ID: https://ror.org/011e9bt93
Award Number: FA9550-14-0398
Funding provided by: United States Air Force Office of Scientific Research
Crossref Funder Registry ID: https://ror.org/011e9bt93
Award Number: FA9550-16-1-0165
Funding provided by: National Science Foundation
Crossref Funder Registry ID: https://ror.org/021nxhr62
Award Number: 1754412
Methods
High speed videos were recorded at 750-2000FPS from tethered, flying Drosophila using high speed cameras (TS4 or IL5, Fastec Imagining, San Diego, CA, USA). Haltere kinematics were extracted using the DeepLabCut python package (Mathis et al. 2018, Nature Neuroscience) or the DLTdv package (Hedrick 2008, Bioinspiration and Biomechanics).
Concurrent videos recorded at 100FPS using an industrial machine vision camera (Point Grey Chameleon3, FLIR, Wilsonville, OR, USA) provided head yaw and wingstroke envelope measurements computed using flyalyzer (https://github.com/michaelrauscher/flyalyzer), a custom MATLAB (The Mathworks, Natick, MA, USA) program.
Files
Files
(102.9 kB)
| Name | Size | Download all |
|---|---|---|
|
md5:f7aa024b8b4c6066b9f52220fe776970
|
19.2 kB | Download |
|
md5:edeac9da07b93730ff0679cfe7b063b1
|
2.6 kB | Download |
|
md5:93937c5ed8e474168c92ab39e630176d
|
5.4 kB | Download |
|
md5:9f6591135eae02d203e6a84d97842b1f
|
9.3 kB | Download |
|
md5:176509d1a31bfac05461afb900ea2b7a
|
17.3 kB | Download |
|
md5:9cea663595db88876c46639ae18202ad
|
13.7 kB | Download |
|
md5:d42725c4f97077df2dc954a78dad306c
|
7.1 kB | Download |
|
md5:b335bc28e77ab0b53a86d8963a6c87f3
|
8.8 kB | Download |
|
md5:e95568cd7c9fe6ff5f61e32a7be0a255
|
9.0 kB | Download |
|
md5:755ff841c2616621ea1cbc9b0a242a36
|
10.5 kB | Download |
Additional details
Related works
- Is cited by
- 10.1101/2022.09.29.509061 (DOI)
- 10.1101/2022.09.29.509061 (DOI)
- Is source of
- 10.5061/dryad.g1jwstqwj (DOI)