Abstract
AbstractFlying insects track turbulent odor plumes to find mates, food and egg-laying sites. To maintain contact with the plume, insects are thought to adapt their flight control according to the distribution of odor in the plume using the timing of odor onsets and intervals between odor encounters. Although timing cues are important, few studies have addressed whether insects are capable of deriving spatial information about odor distribution from bilateral comparisons between their antennae in flight. The proboscis extension reflex (PER) associative learning protocol, originally developed to study odor learning in honeybees, was modified to show hawkmoths, Manduca sexta, can discriminate between odor stimuli arriving on either antenna. We show moths discriminated the odor arrival side with an accuracy of >70%. The information about spatial distribution of odor stimuli is thus available to moths searching for odor sources, opening the possibility that they use both spatial and temporal odor information.
Publisher
Cold Spring Harbor Laboratory
Reference51 articles.
1. Arbas, E. A. , Willis, M. A. and Kanzaki, R. (1993). Organization of goal-oriented locomotion: pheromone-modulated flight behavior of moths. In Biological neural networks in invertebrate neuroethology and robotics. (ed. Beer, R. D. ), Ritzmann, R. E. ), and McKenna, T. M. ), p. Academic Press.
2. The sensory basis of rheotaxis in the blind Mexican cave fish, Astyanax fasciatus
3. Fitting Linear Mixed-Effects Models Using lme4;Journal of Statistical Software,2015
4. Spatial Representation of Feeding and Oviposition Odors in the Brain of a Hawkmoth;Cell Reports,2018
5. Osmotropotaxis inDrosophila melanogaster