Learned magnetic map cues and two mechanisms of magnetoreception in turtles

Goforth, Kayla M.; Lohmann, Catherine M. F.; Gavin, Andrew; Henning, Reyco; Harvey, Andrew; Hinton, Tara L.; Lim, Dana S.; Lohmann, Kenneth J.

Learned magnetic map cues and two mechanisms of magnetoreception in turtles

Kayla M. Goforth (), Catherine M. F. Lohmann, Andrew Gavin, Reyco Henning, Andrew Harvey, Tara L. Hinton, Dana S. Lim and Kenneth J. Lohmann
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Kayla M. Goforth: University of North Carolina at Chapel Hill
Catherine M. F. Lohmann: University of North Carolina at Chapel Hill
Andrew Gavin: University of North Carolina at Chapel Hill
Reyco Henning: University of North Carolina at Chapel Hill
Andrew Harvey: University of North Carolina at Chapel Hill
Tara L. Hinton: University of North Carolina at Chapel Hill
Dana S. Lim: University of North Carolina at Chapel Hill
Kenneth J. Lohmann: University of North Carolina at Chapel Hill

Nature, 2025, vol. 638, issue 8052, 1015-1022

Abstract: Abstract Growing evidence indicates that migratory animals exploit the magnetic field of the Earth for navigation, both as a compass to determine direction and as a map to determine geographical position1. It has long been proposed that, to navigate using a magnetic map, animals must learn the magnetic coordinates of the destination2,3, yet the pivotal hypothesis that animals can learn magnetic signatures of geographical areas has, to our knowledge, yet to be tested. Here we report that an iconic navigating species, the loggerhead turtle (Caretta caretta), can learn such information. When fed repeatedly in magnetic fields replicating those that exist in particular oceanic locations, juvenile turtles learned to distinguish magnetic fields in which they encountered food from magnetic fields that exist elsewhere, an ability that might underlie foraging site fidelity. Conditioned responses in this new magnetic map assay were unaffected by radiofrequency oscillating magnetic fields, a treatment expected to disrupt radical-pair-based chemical magnetoreception4–6, suggesting that the magnetic map sense of the turtle does not rely on this mechanism. By contrast, orientation behaviour that required use of the magnetic compass was disrupted by radiofrequency oscillating magnetic fields. The findings provide evidence that two different mechanisms of magnetoreception underlie the magnetic map and magnetic compass in sea turtles.

Date: 2025
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DOI: 10.1038/s41586-024-08554-y

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