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Bioelectromagnetism
property: the anisotropy of the singlet yield is markedly (by an order of magnitude) larger in RPs com
bining FAD with a partner radical with no signifcant hyperfne interactions, such as O•
2
− , or better a
hypothetic variety of it not subject to fast spin relaxation, conventionally denoted Z• (Lee et al., 2014).
Cryptochromes undergo forward light-induced reactions involving electron transfer to excited state
favin to generate radical intermediates, which correlate with biological activity. A mechanism for
the reverse reaction, namely dark reoxidation of protein-bound favin in Arabidopsis cryptochrome
(AtCRY1) by molecular oxygen, involves the formation of a spin-correlated FADH-superoxide RP (Muller
and Ahmad, 2011). Under conditions of illumination, the cryptochrome photoreceptors are constantly
cycling between inactive (oxidized) and activated (reduced) redox states, such that the net biological
activity results from the sum of the light-induced (activating) and reverse (de-activating) redox reac
tions at any given timepoint. A model of the cryptochrome photocycle incorporating these elements
and an estimation of the quantum efciency of redox state interconversions both in vitro and in vivo
has been recently derived (Procopio et al., 2016). However, when light and dark intervals are given inter
mittently, the plant MFE is observed even when the MF is given exclusively during the dark intervals
between light exposures. Tis indicates that the magnetically sensitive reaction step in the cryptochrome
photocycle must occur during favin reoxidation, and likely involves the formation of reactive oxygen
species (Pooam et al., 2019). A recent model of MFE on the cryptochrome photocycle involves activation
of cryptochrome by favin reduction which triggers conformational change leading to unfolding and
subsequent phosphorylation of the C-terminal domain. Te favin is subsequently reoxidized by reaction
with molecular oxygen that occurs independently of light (Ahmad, 2016). Te efect of an applied MF on
the cryptochrome photocycle occurs during the period of favin reoxidation. Te most likely efect is to
alter the rate constant of reoxidation of the reduced favin intermediates, and thereby alter the lifetime
of the activated state (Figure 5.11). As discussed above, theoretical considerations have argued against a
favin/superoxide radical pair, which is formed in the course of favin reoxidation as the magnetosensing
intermediate in cryptochromes (Hore and Mouritsen, 2016); however, cryptochrome localized within liv
ing cells is in contact with many cellular metabolites, which, moreover, can move into the favin pocket
FIGURE 5.11 Model of MFE on the cryptochrome photocycle, see text for explanation. (Modifed from Pooam
et al. (2019).)