Abstract
Moving animals experience wide-field optic flow due to the displacement of the retinal image during motion. These cues provide information about self-motion and are important for flight control and stabilization, and for more complex tasks like path integration. While in honeybees and bumblebees the use of wide-field optic flow in behavioral tasks is well investigated, little is known about the underlying neuronal processing of these cues. Furthermore, there is a discrepancy between the temporal frequency tuning observed in most motion-sensitive neurons described so far from the optic lobe of insects and the velocity tuning that has been shown for many behaviors. Here we investigated response properties of motion-sensitive neurons in the central brain of bumblebees. Extracellular recordings allowed us to present a large number of stimuli to probe the spatiotemporal tuning of these neurons. We presented moving gratings that simulated either front-to-back or back-to-front optic flow and found three response types. Direction-selective responses of one of the groups matched those of TN-neurons, which provide optic flow information to the central complex, while the other groups contained neurons with purely excitatory responses that were either selective or non-selective for stimulus direction. Most recorded units showed velocity-coding properties at lower angular velocities, but showed spatial frequency dependent responses at higher velocities. Based on behavioral data, neuronal modelling work has previously predicted the existence of non direction-selective neurons with such properties. Our data now provides physiological evidence for these neurons and shows that neurons with TN-like properties exhibit a similar velocity-dependent coding.
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