Magnetoreception refers to the ability of some animals to sense Earth's magnetic field and make use of it for navigation. Still, the underlying mechanisms remain unknown. "To solve this question might not only satisfy neuroscientific curiosity but also lead to new molecular methods," said Prof. Dr. Gil Gregor Westmeyer. He is the principal investigator of the study at the interface of neuroscience and molecular imaging, and his team is affiliated both with Helmholtz Zentrum München and TUM. "Reverse-engineering the magnetoreceptor may lead to synthetic biology techniques for remotely controlling molecular processes with magnetic fields." To reach this goal, Westmeyer and his team wanted to establish a model to study magnetoreception.

The scientists focused their work on zebrafish, and distally related medaka fish because they are vertebrate animals that can be genetically addressed and analyzed well under the microscope.* The researchers found that adult fish of both species change their swimming trajectories in response to a change in the direction of the Earth magnetic field that was experimentally introduced while carefully controlling for confounding variables. Interestingly, this effect also occurred in the absence of visible light such that a photon-independent mechanism has to be assumed.

"In this model, we can now look for previously unidentified magnetoreceptor cells, which our behavioral experiments predicted would involve magnetic material," said co-first author Ahne Myklatun, a graduate student in the Westmeyer laboratory.

In addition, the researchers were able to show a similar magnetic field-dependent effect in young fish larvae. "This is a decisive advantage because in their early developmental stages, the fish are still almost transparent," said Antonella Lauri, a postdoctoral fellow and joint lead author. "Thus, we can use imaging techniques to study the brain of the fish during behavioral runs with changing magnetic fields." The scientists were already able to identify a candidate region in the brain -- a track that could now lead to the unknown magnetic receptor cells.

Gil Gregor Westmeyer, principal investigator on this ERC-funded study, concludes: "Magnetoreception is one of the few senses whose mechanism is not understood. The kind of multidisciplinary work we present here will ultimately lead to an understanding of the biophysical mechanism of magnetoreception and its underlying neuronal computation. These findings could also offer interesting approaches to engineer biological systems for the remote control of molecular processes with magnetic fields."