Cognitive robustness in a new insect model of extended longevity

Human life expectancy has jumped by several decades in the last century, but the healthspan has not followed suit. The ageing population has come with an increased prevalence of neurodegenerative disease, and insects have proven to be valuable models of these conditions and their associated cognitive decline. The Heliconius butterfly genus is an emerging system in insect cognition, having recently evolved a significant expansion in neural centres of learning and memory, alongside enhanced stability of visual long-term memory in comparison with their close relatives in the Heliconiini tribe. This is linked to the cognitive demands imposed by Heliconius spatially-faithful foraging behaviour for a protein-rich diet of pollen, and co-occurs with a dramatic lifespan extension in this genus over the other Heliconiini outgroups. Here, we investigate whether the Heliconius cognitive healthspan is similarly discrepant, or if any cognitive decline is instead delayed in accordance with their lifespan extension. We first report evidence that investment in learning and memory circuits co-evolves with Heliconiini lifespan. We then conduct learning and memory assays across the lifespans of a representative longer-lived Heliconius, H. hecale, and the shorter-lived Heliconiini outgroup, Dryas iulia. Across both species, and particularly in H. hecale, we find evidence for cognitive robustness in late life, in contrast to evidence for widespread cognitive declines in insects. Our results add a new taxonomic order to the study of age-related memory impairment, and suggest Heliconius as a valuable model system for mechanistic studies of the maintenance of neurological health in the context of extended life.