Flies as Ship Captains? Digital Evolution Unravels Selective Pressures to Avoid Collision in Drosophila
This work addresses the evolutionary basis of specific behavioral strategies in insects, but it is incremental as it builds on known observations without broad new insights.
The study investigated whether the collision avoidance strategy observed in flies, which uses optic flow to decide which individual stops, could evolve under selective pressure for avoiding collisions. Using digital evolution, they found the strategy evolves only under narrow, error-free conditions, suggesting real flies may require additional factors.
Flies that walk in a covered planar arena on straight paths avoid colliding with each other, but which of the two flies stops is not random. High-throughput video observations, coupled with dedicated experiments with controlled robot flies have revealed that flies utilize the type of optic flow on their retina as a determinant of who should stop, a strategy also used by ship captains to determine which of two ships on a collision course should throw engines in reverse. We use digital evolution to test whether this strategy evolves when collision avoidance is the sole penalty. We find that the strategy does indeed evolve in a narrow range of cost/benefit ratios, for experiments in which the "regressive motion" cue is error free. We speculate that these stringent conditions may not be sufficient to evolve the strategy in real flies, pointing perhaps to auxiliary costs and benefits not modeled in our study