Inhibitory Control of Walking in Olfactory Search
Inhibitory control explains locomotor statistics in walking Drosophila
Hannah C. Gattuso, Karin A. van Hassel, Jacob D. Freed, Kavin M. Nuñez, Beatriz de la Rea, Christine E. May,
G. Bard Ermentrout, Jonathan D. Victor, and Katherine I. Nagel
Proc. Natl. Acad. Sci. USA. doi: 10.1073/pnas.2407626122 (2025)
Abstract
In order to forage for food, many animals regulate not only specific limb movements but
the statistics of locomotor behavior, switching between long-range
dispersal and local
search depending on resource availability. How premotor circuits regulate locomotor statistics
is not clear. Here, we analyze and model locomotor statistics and their modulation
by attractive food odor in walking Drosophila. Food odor evokes three motor regimes in
flies: baseline walking, upwind running during odor, and search behavior following odor
loss. During search, we find that flies adopt higher angular velocities and slower ground
speeds and turn for longer periods in the same direction. We further find that flies adopt
periods of different mean ground speed and that these state changes influence the length
of odor-evoked
runs. We next developed a simple model of neural locomotor control that
suggests that contralateral inhibition plays a key role in regulating the statistical features
of locomotion. As the fly connectome predicts decussating inhibitory neurons in the premotor
lateral accessory lobe (LAL), we gained genetic access to a subset of these neurons
and tested their effects on behavior. We identified one population whose activation induces
all three signature of local search and that regulates angular velocity at odor offset. We
identified a second population, including a single LAL neuron pair, that bidirectionally
regulates ground speed. Together, our work develops a biologically plausible computational
architecture that captures the statistical features of fly locomotion across behavioral states
and identifies neural substrates of these computations.
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