Abstract
A visual magnetic sense in migratory birds has been hypothesized to rely on a radical pair reaction in the protein cryptochrome. In this model, magnetic sensitivity originates from coherent spin dynamics, as the radicals couple to magnetic nuclei via hyperfine interactions. Prior studies have often neglected the electron–electron dipolar (EED) coupling from this hypothesis. We show that EED interactions suppress the anisotropic response to the geomagnetic field by the radical pair mechanism in cryptochrome and that this attenuation is unlikely to be mitigated by mutual cancellation of the EED and electronic exchange coupling, as previously suggested. We then demonstrate that this limitation may be overcome by extending the conventional model to include a third, nonreacting radical. We predict that hyperfine effects could work in concert with three-radical dipolar interactions to tailor a superior magnetic response, thereby providing a new principle for magnetosensitivity with applications for sensing, navigation, and the assessment of biological magnetic field effects.
Highlights
A visual magnetic sense in migratory birds has been hypothesized to rely on a radical pair reaction in the protein cryptochrome
Recent calculations show that electron−electron dipolar (EED) interactions can abolish the “quantum needle”, a sharp feature in the directional magnetic field effect (MFE) that was predicted to boost the acuity of the compass,[29,33] and may nullify the Larmor resonance,[33,34] a phenomenon observed in some behavioral studies employing radiofrequency magnetic fields to test for the radical pair mechanism (RPM).[35]
D compensation help recover the anisotropies of the hypothetical scenario without inter-radical interactions? We found that exchange interactions matching the J/D cancellation conditions did not restore the MFEs to levels significantly exceeding those in the presence of EED coupling alone
Summary
A visual magnetic sense in migratory birds has been hypothesized to rely on a radical pair reaction in the protein cryptochrome. (d) Relative anisotropy Γ for the [FADH/Z] RPM model from (b) as a function of the exchange coupling constant J = J12.
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