Abstract
Monarch butterflies in North America migrate south each autumn, but the mechanisms that initiate their migratory flight remain incompletely understood. We investigated environmental, developmental, and genetic factors that contribute to directional flight by testing summer and autumn-generation monarchs in three flight simulators: two at ground level (with and without wind blockage) and a novel balloon-based system that raised butterflies 30 meters into the air. Monarchs reared under autumn-like conditions in a growth chamber during the summer were also tested to explore the influence of developmental cues. Autumn generation monarchs demonstrated significant southwestern flight orientation, observed exclusively in the balloon simulator, underscoring the importance of high-altitude flight for migratory behavior. Summer generation monarchs reared under autumn-like conditions displayed southward orientation, larger wing sizes, and partial reproductive diapause, indicating specific seasonal environmental cues that are sufficient to induce migratory traits. In contrast, a lab line of monarchs reared in captivity since 2016 exhibited diminished wing size and reduced orientation ability, even when raised outdoors in the autumn, consistent with a loss of migratory traits in the absence of migration. Surprisingly, butterflies in the balloon simulator tended to orient upwind, which suggests that wind may also serves as a directional cue during migration. These findings highlight the critical roles of altitude, wind, and environmental cues in monarch migration and validate the balloon flight simulator as a powerful tool for studying migratory behavior. This research advances our understanding of the initiation of monarch migration and informs strategies for conservation efforts amidst environmental change.
Published Version
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