Study finds genetic evidence that magnetic navigation guides loggerhead sea turtles home
Loggerhead sea turtles that nest on beaches with similar magnetic fields are genetically similar, according to UNC-Chapel Hill researchers.
New research from the University of North Carolina at Chapel Hill provides valuable insight into the navigation and nesting behaviors of loggerhead sea turtles that could inform future conservation efforts. Loggerhead sea turtles that nest on beaches with similar magnetic fields are genetically similar to one another, according to a new study by UNC-Chapel Hill biologists Kenneth J. Lohmann and J. Roger Brothers. The study was published today in the journal Current Biology.
Key takeaways include:
- Magnetic fields are the strongest predictor of genetic similarity among nesting loggerhead sea turtles, regardless of the geographic proximity or environmental traits of nesting beaches.
- The findings support previous research from Lohmann and Brothers, which indicated that adult loggerhead sea turtles use magnetic fields to find their way back to the beach where they themselves hatched. The new research implies that sometimes the turtles mistakenly nest at a different beach with a similar magnetic field, even if that beach is geographically far away from the beach on which they hatched – like on the opposite coast of Florida.
- Conservation efforts should note the importance of a beach’s magnetic field for attracting loggerhead sea turtles. Sea walls, power lines and large beachfront buildings may alter the magnetic fields that turtles encounter.
- This research is especially relevant in North Carolina, as it explains how loggerhead sea turtles that are hatched on North Carolina beaches return to those same beaches after a migration across the entire Atlantic Ocean basin.
“Loggerhead sea turtles are fascinating creatures that begin their lives by migrating alone across the Atlantic Ocean and back. Eventually, they return to nest on the beach where they hatched – or else, as it turns out, on a beach with a very similar magnetic field,” said Kenneth Lohmann, professor of biology in the College of Arts and Sciences at UNC-Chapel Hill. “This is an important new insight into how sea turtles navigate during their long-distance migrations. It might have important applications for the conservation of sea turtles, as well as other migratory animals such as salmon, sharks and certain birds.”