Seizures in a Bang-Sensitive Epilepsy Model Impact Associative Learning in Drosophila Larvae

The seizures associated with epilepsy in humans may impact their learning and memory, however, the mechanism of how the seizures themselves lead to these deficits is not clear. Drosophila mutant flies that have seizure phenotypes have been used effectively as a model for human epilepsy. In this study, we tested whether stimuli that induce seizures in Drosophila para ^bss mutants, a mutation in the fly sodium channel gene, affect learning. We used an adult conditioned courtship model and both rewarding and aversive associative learning assays in Drosophila larvae. For the conditioned courtship model, males exposed to mated females show depressed mating when placed with virgin females, suggesting that they learned from their rejection. In the larval paradigm, larvae are trained by pairing an odor (octanol or amyl acetate) with a reward (fructose) or an aversive stimulus (electrical shock) and then tested for learning by looking for movement towards or away from the odor they were trained on in a choice assay. We found that our wildtype CS stock and para ^bss mutants did not respond to octanol as a neutral odor but as an aversive one. Therefore, octanol was used to train in a positive associate learning task and amyl acetate was used in aversive assays. Our para ^bss stock performed almost as well as wildtype in learning in all of these assays, although other labs had reported learning deficits in these mutants. In addition, seizure induced through vortex in the adult learning paradigm and cold in the larval assay disrupted learning. These results suggest that learning deficits may be directly due to seizures rather than some other effect of the mutant.