Main Menu (Mobile)- Block
Main Menu - Block
Abstract
After finding food, a foraging animal must decide whether to continue feeding or to explore the environment for potentially better options. One strategy to negotiate this tradeoff is to perform local searches around the food while repeatedly returning to feed. We studied this behavior in flies and used genetic tools to uncover the underlying behavioral strategies. Over time, flies gradually expand their search, shifting from primarily exploiting food sources to exploring the environment, a change likely driven by increased satiety. We found that flies' search patterns preserve these dynamics even as the overall range of the search is modulated by starvation. In contrast, search induced by optogenetic activation of sugar-sensing neurons does not show these dynamics. We asked what navigational strategies underlie local search. Using a generative model, we found that a change in locomotor pattern after food consumption could account for repeated returns to the food, but not the relatively direct return trajectories that flies make even from far away. Such trajectories likely rely on alternative strategies, such as path integration or sensory taxis. We tested this by individually silencing their likely neural components, the compass system, olfaction, and hygrosensation. The only substantial effect was from perturbing hygrosensation, which reduced the number of long exploratory trips with subsequent return to the food. Our study illustrates that local search comprises multiple behavioral features that evolve over time based on both internal and external factors, providing a path toward uncovering the underlying neural mechanisms.
