2017
DOI: 10.1038/srep42228
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Millitesla magnetic field effects on the photocycle of an animal cryptochrome

Abstract: Drosophila have been used as model organisms to explore both the biophysical mechanisms of animal magnetoreception and the possibility that weak, low-frequency anthropogenic electromagnetic fields may have biological consequences. In both cases, the presumed receptor is cryptochrome, a protein thought to be responsible for magnetic compass sensing in migratory birds and a variety of magnetic behavioural responses in insects. Here, we demonstrate that photo-induced electron transfer reactions in Drosophila mela… Show more

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Cited by 81 publications
(98 citation statements)
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“…The spin states of these chemical intermediates, in turn, influence the rate of CRY activation, which is transduced into neuronal impulses through an as yet unknown pathway. Even though sensitivity to weak MF could hitherto only be demonstrated in the plant Arabidopsis thaliana [36] and fruit fly (Drosophila melanogaster) CRY [37], a wealth of evidence supports the involvement of CRY in the ability of birds to orient to the geomagnetic field [35]. From recent data, the magnetic sense in birds is based on a type IV CRY (CRY 4) localized in cones of the avian retina [38].…”
Section: Cryptochromes Of Mammalsmentioning
confidence: 99%
“…The spin states of these chemical intermediates, in turn, influence the rate of CRY activation, which is transduced into neuronal impulses through an as yet unknown pathway. Even though sensitivity to weak MF could hitherto only be demonstrated in the plant Arabidopsis thaliana [36] and fruit fly (Drosophila melanogaster) CRY [37], a wealth of evidence supports the involvement of CRY in the ability of birds to orient to the geomagnetic field [35]. From recent data, the magnetic sense in birds is based on a type IV CRY (CRY 4) localized in cones of the avian retina [38].…”
Section: Cryptochromes Of Mammalsmentioning
confidence: 99%
“…Ritz, Adem and Schulten were the first to speculate that the underlying radical pair could be formed by photo-excitation in the animals' eyes in cryptochromes [11], a class of blue-light sensitive flavo-proteins that shares some similarity with photolyases [12]; this supposition still applies;. To date, cryptochromes are the only vertebrate proteins known to form radical pairs in a physiologically significant photoreaction and their relevancy to magnetoreception has indeed been implicated in a multitude of studies [13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28]. The reader is referred to the many reviews on this subject for a more detailed exposition [10,27,29,30].…”
Section: Introductionmentioning
confidence: 99%
“…There is significant but largely circumstantial evidence in support of this hypothesis (4): the avian compass is known to be light dependent (7,8), a proof-of-principle model radical-pair compass has been demonstrated (9), and cryptochromes, the proposed receptor proteins (2), form magnetically sensitive radical pairs when excited in vitro with blue light (10,11). However, it is the disorientation of birds exposed to very weak radiofrequency magnetic fields (1,12) that arguably rules out the competing hypotheses based on superparamagnetic (13) or ferrimagnetic particles (14).…”
Section: Introductionmentioning
confidence: 99%