Alternative radical pairs for cryptochrome-based magnetoreception

There is growing evidence that the remarkable ability of animals, in particular birds, to sense the direction of the Earth''s magnetic field relies on magnetically sensitive photochemical reactions of the protein cryptochrome. It is generally assumed that the magnetic field acts on the radical pair FAD^•− TrpH^•+] formed by the transfer of an electron from a group of three tryptophan residues to the photo-excited flavin adenine dinucleotide cofactor within the protein. Here, we examine the suitability of an FAD^•− Z^•] radical pair as a compass magnetoreceptor, where Z^• is a radical in which the electron spin has no hyperfine interactions with magnetic nuclei, such as hydrogen and nitrogen. Quantum spin dynamics simulations of the reactivity of FAD^•− Z^•] show that it is two orders of magnitude more sensitive to the direction of the geomagnetic field than is FAD^•− TrpH^•+] under the same conditions (50 µT magnetic field, 1 µs radical lifetime). The favourable magnetic properties of FAD^•− Z^•] arise from the asymmetric distribution of hyperfine interactions among the two radicals and the near-optimal magnetic properties of the flavin radical. We close by discussing the identity of Z^• and possible routes for its formation as part of a spin-correlated radical pair with an FAD radical in cryptochrome.