Sensorimotor delays constrain robust locomotion in a 3D kinematic model of fly walking

Karashchuk, Lili; (Lisa) Li, Jing Shuang; Chou, Grant M.; Walling-Bell, Sarah; Brunton, Steven L.; Tuthill, John C.; Brunton, Bingni W.

doi:10.1101/2024.04.18.589965

2024

DOI: 10.1101/2024.04.18.589965

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Sensorimotor delays constrain robust locomotion in a 3D kinematic model of fly walking

Lili Karashchuk,

Jing Shuang (Lisa) Li,

Grant M. Chou

et al.

Abstract: Walking animals must maintain stability in the presence of external perturbations, despite significant temporal delays in neural signaling and muscle actuation. Here, we develop a 3D kinematic model with a layered control architecture to investigate how sensorimotor delays constrain robustness of walking behavior in the fruit fly, Drosophila. Motivated by the anatomical architecture of insect locomotor control circuits, our model consists of three component layers: a neural network that generates realistic 3D … Show more

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Inhibitory circuits generate rhythms for leg movements during Drosophila grooming

Syed,

Ravbar,

Simpson

2024

Preprint

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SummaryLimbs execute diverse actions coordinated by the nervous system through multiple motor programs. The basic architecture of motor neurons that activate muscles which articulate joints for antagonistic flexion and extension movements is conserved from flies to vertebrates. While excitatory premotor circuits are expected to establish sets of leg motor neurons that work together, our study uncovered an instructive role for inhibitory circuits. Using electron microscopy data for theDrosophilanerve cord, we categorized ∼120 GABAergic inhibitory neurons from the 13A and 13B hemi-lineages into classes based on similarities in morphology and connectivity. By mapping their synaptic partners, we uncovered redundant pathways for inhibiting specific groups of motor neurons, disinhibiting antagonistic counterparts, or inducing alternation between flexion and extension. We tested the function of specific inhibitory neurons through optogenetic activation and silencing, using quantitative leg movement assays for coordination during grooming. Behavior experiments and modeling demonstrate that inhibition can induce rhythmic motion, highlighting the importance of inhibitory circuits in motor control.

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Inhibitory circuits generate rhythms for leg movements during Drosophila grooming

Syed,

Ravbar,

Simpson

2024

Preprint

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Sensorimotor delays constrain robust locomotion in a 3D kinematic model of fly walking

Cited by 1 publication

References 83 publications

Inhibitory circuits generate rhythms for leg movements during Drosophila grooming

Inhibitory circuits generate rhythms for leg movements during Drosophila grooming

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