Are stress responses to geomagnetic storms mediated by the cryptochrome compass system?
Abstract
A controversial body of literature demonstrates associations
of geomagnetic storms (GMS) with numerous cardiovascular, psychiatric
and behavioural outcomes.
Various melatonin hypotheses of GMS have suggested that temporal variation in the geomagnetic field (GMF) may be acting as an additional zeitgeber
(a temporal synchronizer) for circadian rhythms, with GMS somehow
interfering with the hypothesized system.
The cryptochrome genes are
known primarily as key components of the circadian pacemaker, ultimately
involved in controlling the expression of the hormone melatonin.
Cryptochrome is identified as a clear candidate for mediating the effect
of GMS on humans, demonstrating the prior existence of several crucial
pieces of evidence.
A distinct scientific literature demonstrates the
widespread use of geomagnetic information for navigation across a range
of taxa.
One mechanism of magnetoreception is thought to involve a
light-dependent retinal molecular system mediated by cryptochrome,
acting in a distinct functionality to its established role as a
circadian oscillator.
There is evidence suggesting that such a
magnetosense—or at least the vestiges of it—may exist in humans.
This
paper argues that cryptochrome is not acting as secondary geomagnetic
zeitgeber to influence melatonin synthesis.
Instead, it is hypothesized
that the cryptochrome compass system is mediating stress responses more
broadly across the hypothalamic–pituitary–adrenal (HPA) axis (including
alterations to circadian behaviour) in response to changes in the GMF.
Two conceptual models are outlined for the existence of such
responses—the first as a generalized migrational/dispersal strategy, the
second as a stress response to unexpected signals to the magnetosense.
It is therefore proposed that GMS lead to disorientation of hormonal
systems in animals and humans, thus explaining the effects of GMS on
human health and behaviour.
1. Introduction
(a) Geomagnetic navigation in animals
The geomagnetic field (GMF) conveys orientational and
positional information of substantial utility to migrating animals.
Magnetoreception is thought to exist across a phylogenetically
widespread array of taxa, including molluscs, insects, bony fish,
amphibians, bats, rodents, artiodactylans, cetaceans, carnivorans and
avian species (there are many good reviews [1–3]).
Geomagnetic senses have a small overall physiological footprint and are
redundantly integrated with other navigational and sensory stimuli in a
complex fashion.
For these reasons, they have often confounded
scientific investigation, and it is only over the last few decades that
their mechanisms and functionality have started to become elucidated.
The majority of well-studied magnetodetection systems can be broadly
divided into two categories: permanent ferromagnetic crystals normally
found in the ethmoid sinuses of vertebrates, or a cryptochrome-mediated
radical-pair based paramagnetic detection located in the eye. Many bird
species appear to have both systems working in tandem to produce a
detailed magnetic map. These senses appear to be extremely sensitive—in
order for the magnetic map to function, birds must be able to detect
naturally occurring local changes in magnetic field strength that are
down to perhaps 10 nT, equivalent to just a few miles or less [1].
Thresholds in the region 10–200 nT have been shown experimentally in
birds and honeybees, and inferred for homing pigeons and whales [3].
(b) Cryptochrome-based magnetodetection
The radical-pair mechanism has been proposed as one of only a
few molecular features that might plausibly be influenced by the
Earth's magnetic field [4],
with the yield of a biochemical reaction proceeding via a
spin-correlated radical-pair-based reaction being sensitive to the
orientation of an external magnetic field. A later theoretical
refinement of the model proposed that the retina is well suited as an
ordered structure for an array of molecules configured in various
alignments with the GMF [5],
with the product of the radical pair intermediate detected by the
existing visual reception system. It was also hypothesized that
cryptochrome was the most promising candidate molecule—it is the only
known photoreceptor in vertebrates shown to be able to form a radical
pair upon photoexcitation [5].
Mounting inferential evidence now supports a role for cryptochrome in
avian magnetodetection: the hypothesized eye-localized, paramagnetic
cryptochrome-based magnetodetection has a series of biophysical
signatures, including (but not limited) to the following (for references
and a more complete discussion, see reviews, [1–3,6]): (i) Gene expression profile:
a high cytosolic localization of cryptochrome in avian retinal ganglion
cells and co-localization with neuronal activity markers during
magnetic orientation suggests a role of cryptochrome as a magnetic
compass detector (beyond its established role as a circadian oscillator)
[7]. (ii) The avian compass is an inclination compass:
the radical-pair method is known to operate as an inclination compass
(directional information is derived from the inclination of the field
lines rather than their polarity). An inclination compass has been
documented for geomagnetic navigation in every bird species tested, also
revealing a corresponding insensitivity to polarity. (iii) Geomagnetic navigation involves the eyes and is light-dependent:
the cryptochrome model proposes that magnetoreception involves photon
absorption as a first step for creation of radical pairs, and therefore
predicts that geomagnetic navigation will be dependent on a specific
wavelength of light. It has been shown that magnetic orientation is
wavelength dependent under low-intensity monochromatic light, with birds
orientating well under blue wavelength, but are generally challenged
under red wavelengths. (iv) Sensitivity to oscillating magnetic fields in the low radio-frequency range:
these fields are expected to affect radical-pair reactions and compete
with the effects of the GMF, but would not interfere with
magnetite-based magnetodetection. Experiments with such fields have been
shown to disrupt magnetic orientation behaviour of migratory birds.
These results provide the strongest, albeit indirect, evidence that the
biophysical mechanism underlying the magnetic compass of birds involves
the radical-pair reaction, with such effects hard to reconcile with
other mechanisms.
(c) A human magnetosense?
Somewhat surprisingly, while a human magnetosense is not
widely accepted, there is accumulating evidence to suggest that such a
sense—or at least the vestiges of it—may exist. It has recently been
proposed that magnetoreception may be a general feature of at least
mammals [4], and also that animals without a magnetosense may be the exception, rather than the rule [5].
The majority of human evolution involved migrational or nomadic
lifestyles until the onset of sedentarization around 10 000 years ago [8],
providing a clear functional utility for such a sense. In 1987, a
meta-analysis of several studies directly testing for human geomagnetic
orientation revealed a statistically significant result [9].
Recent studies with more sophisticated experimental design have
confirmed these results, revealing that weak magnetic fields can trigger
evoked potentials in human subjects [10]. Further human experimental studies have revealed that the visual sensitivity of man is influenced by changes to the GMF [11],
interpreted as supporting evidence for the radical-pair retinal model
in humans. Further publications have revealed that the fundamental
biological components for magnetoreception are present in humans.
Ferromagnetic structures have been identified in human sinuses [12]. Moreover, recent experiments with Drosophila have revealed that the human cryptochrome CRY2 gene has functional magnetoreceptive abilities [13]. These experiments involved entraining Drosophila to navigate using a magnetic field, with the response shown to be blue-light dependent, thus implicating cryptochrome [14]. Moreover, cryptochrome-knockout Drosophila
could not navigate in response to the magnetic field, providing the
first direct evidence for the role of cryptochrome in magnetic
navigation. In a subsequent transgenic experiment, the human
cryptochrome CRY2 gene was revealed to rescue the magnetic navigation
abilities of the knockout Drosophila, thus revealing that the human gene is functionally magnetosensitive [13].
(d) Geomagnetic storms
The GMF has a maximum field strength of around 70 µT at the
geographical poles (where the field is near vertical) to less than 30 µT
at the geomagnetic equator (where the field is parallel to the
terrestrial plain). Coronal mass ejections can occasionally be directed
towards the Earth. These can deliver a huge number of high-energy ions
to the ionosphere, which are sufficient to cause relatively minor
alterations to the strength and the direction of the magnetic field.
Such events are dubbed ‘geomagnetic storms’ (GMS). These global
disturbances can last from several hours to days, with the literature
generally defining a geomagnetic storm as involving 24 h planetary
average changes to the GMF of as little as around 30 nT [15–17].
Such storms occur on average once every 10 days or so, but do not occur
with an even distribution. Instead, solar activity reveals a number of
quasi-periodic oscillations, the most prominent of which is the
approximately 11.5 year solar cycle. Furthermore, GMS tend to be more
frequent at the equinoxes, and more extreme at higher latitudes [18,19].
(e) Geomagnetic storms and human health
A large, complex, and often controversial body of literature
has linked elevated geomagnetic activity (GMA) with a range of human
psychological, neurological, cardiovascular (CV), immunological and
behavioural outcomes (see electronic supplementary material, table). The
roots of this literature [20]
lies with Russian biological science, where studies revealed a number
of health associations of GMS of various strength and reproducibility,
with many of these associations since investigated in the Western
literature [19].
Owing to space constraints, selected evidence for the key findings is
outlined below. However, the electronic supplementary material,
table includes a detailed reference list.
While early Western studies on the CV system were controversial with some notable negative results [21] and a retraction [22],
later studies have revealed positive associations of GMS with
myocardial infarction, stroke, blood pressure, capillary blood flow and
an inverse correlation with heart rate variability (HRV) [18,19,23,24]. One study observed that in years of peak GMS activity, patients admitted for myocardial infarction increased 25 per cent [25];
other studies have reported a similar relationship, accounting for a 5
per cent increase in mortality in maximal solar years [26]. Moreover, these epidemiological studies are supported by evidence from both human [27,28] and animal [29,30] physiological studies that reveal changes to blood pressure and HRV in relation to geomagnetic disturbances.
With regard to the psychiatric literature, associations have
been revealed between GMA and increased hospitalizations for depression
[31] and ambulance callouts for mental disorders in general [32],
with one well-cited study reporting an increase of 36 per cent in
hospital admissions for males with a diagnosis of depression during
periods of high GMA [31].
However, such psychiatric findings have not always been repeated and
remain somewhat contentious (see electronic supplementary material,
table and [18,19] for discussion).
Associations have also been demonstrated across wider health studies, correlating GMA with the total number of deaths [33]. Correlations have also been reported between solar cycles and longevity [34], although such findings remain equivocal [35]. A further series of studies have revealed associations between the solar cycle and flu pandemics [36], and a similar relationship was recently reported with papillomavirus infections [37]. Relationships have also been observed between GMA and sudden infant death syndrome [38] and epilepsy [39].
One of the few large literature reviews on GMS made the definite
conclusion that GMA has an effect on human CV health, and the less
certain conclusion that there may be an association between GMA and
admissions for mental illness [18].
A review of the vast Russian magnetobiology literature concluded that
‘the totality of the matter described here strongly supports the
hypothesis that the GMF disturbances correlate with the general human
condition’ [19].
Associations of GMA with certain parameters—in particular, the CV
system and melatonin suppression—are now so heavily reproduced that the
associations themselves are not necessarily the subject of controversy.
Rather, the fundamental question now relates to causation versus
correlation. However, the obvious confounders—seasonality and
latitude—are often controlled for, and the results have often been
confirmed in various human and animal physiological studies both during
GMS and using applied Earth-strength magnetic fields (electronic
supplementary material, table). Therefore, serious consideration has
been applied to a rational biological basis for these associations.
(f) The melatonin hypothesis of geomagnetic storms
A plausible mechanism of biological action of GMS has
confounded biological sciences for decades—one of the primary reasons
why the above findings are often treated with caution. When searching
for rational explanations for the aetiology of GMS, a striking feature
is their small magnitude—as little as 0.1 per cent or less of the
background GMF, with typical directional changes of the field a fraction
of a degree. This poses a significant problem when considering
plausible biophysical mechanisms. While numerous models have been
proposed (see [18,19,40]
for discussion), most remain unclear and unsubstantiated by evidence.
However, a series of hypotheses that argue a role for melatonin and the
circadian system have gained the most widespread support [15,16,18,31,38,39,41,42].
Light is detected by the non-classical photoreceptor
melanopsin in the eye, with the photic information conveyed to the
suprachiasmatic nucleus (SCN), where it acts as the principal
environmental synchronizer of the master mammalian circadian pacemaker,
and is used to modulate coupled transcription/translation feedback loops
[43–46].
This involves a molecular oscillator of several components including
the Period genes (PER1, PER2 and PER3) and cryptochrome genes (CRY1 and
CRY2). The SCN acts as master pacemaker that regulates many functions
throughout the organism including endocrine functions (including
melatonin and glucocorticoids), behavioural outputs (body temperature,
sleep/wake cycles), metabolism and liver function. The pineal gland is
the source of circulating melatonin, plasma concentrations of which are
higher during the biological night than the day, and it is fundamentally
involved in regulating the sleep–wake cycles. Retinal exposure to light
at night, via the above outlined pathways, produces short-term
suppression of night-time melatonin secretion in an intensity-dependent
manner, which can result in the modulation of normal circadian rhythms.
The previously proposed melatonin hypothesis of GMS [15,16,18,31,38,39,41,42]
is predicated on observations that GMA or applied magnetic fields in
the geomagnetic range have been associated with lower mean nocturnal
melatonin secretion (or its major metabolite 6-hydroxymelatonin-sulfate:
6-OHMS) in studies of both healthy individuals and CV patients [15,16,41,47,48]. Such findings have been confirmed in animal experimental studies [49–54], although some negative results have been obtained [52,54]
(see electronic supplementary material, table). Moreover, melatonin
plays a central role in the regulation of diverse biological functions,
and the other observed relationships of GMA (e.g. CV, psychiatric and
immunological) all concern traits that are possibly influenced
downstream by the effects of melatonin disturbance [45]. For example, there is evidence for the involvement of melatonin in various cardiopathologies [55,56].
Previous authors have therefore suggested that the influences of GMA on
the CV system could be via a disruption of melatonin synthesis [47,48,57,58],
with the effects transmitted to the CV system via melatonin action on
the adrenal gland influencing glucocorticoid and cortisol production [59].
With the psychiatric findings, it has recently been suggested that the
circadian system may be more directly involved in the aetiology of
psychiatric disorders [60]. Marked changes are observed in the circadian systems of psychiatric patients [44], and circadian clock genes (including CRY2 [61]) have been associated with almost all neuropsychiatric disorders, albeit with some conflicting results [44].
Disrupted melatonin action could have further widespread deleterious
effects on human health: it is an immunoenhancing modulator (thereby
potentially influencing influenza and other infections) [36], is known to act as an anti-oxidant [45], is an endogenous anticonvulsant (thereby potentially influencing epilepsy) [39] and has been linked with sudden infant death syndrome [38].
While there is evidence of melatonin suppression in
response to changes in the GMF, fundamental questions remain concerning
the putative biophysical and molecular basis for such associations and
the underlying biological rationale for such circadian
behaviour. Below, the evidence for the melatonin hypothesis is
disinterred, reframed within the context of recent work on geomagnetic
navigational magnetoreception, and extended: first, to hypothesize a
specific biological candidate, and secondly, to hypothesize a novel but
plausible theoretical framework.
2. Cryptochrome as the prime candidate for the effects of geomagnetic storms on humans
Cryptochrome immediately presents itself as the prime
candidate for a role linking GMS with the circadian system: of its two
established functions, one is to act as a geomagnetic compass, the other
is to act as a circadian oscillator. However, this is perhaps a
somewhat naive appraisal of cryptochrome, as these roles are thought to
be entirely distinct. During preparation and review of this manuscript,
cryptochrome has, in a related manner, been suggested as a candidate
gene underlying the observed relationships between the solar cycle and
influenza pandemics [36] and suggested as the candidate for the controversial effects of anthropogenic sources of EMFs on human health [62,63].
These reviews are an ideal complement to this paper owing to their
distinct focus (see also the electronic supplementary material for
further discussion of PF-EMFs).
(a) The evidence for cryptochrome
(i) Similarity of human and avian expression of cryptochrome.
Quantitative RT-PCR and immunohistochemistry of human tissue revealed a
relative abundance of CRY2 transcripts localized to the inner retina
and that it is also localized within the cytoplasm of some cells in the
ganglion cell layer [64].
This originally led to suggestions that cryptochrome may perform a
secondary retinal function of photo-entrainment of the circadian system.
However, it is now known that melanopsin, rather than CRY2, primarily
performs such a role [43],
although some photo-entraining functionality of CRY2 cannot be
excluded. Instead, it should be highlighted that this expression profile
is similar to avian species, where CRY1 has also been shown to have a
high cytosolic expression in ganglion cells (see electronic
supplementary material, figure for visual comparison). This same
expression, in avian species, has been inferred as evidence for the
involvement of cryptochrome in magnetodetection [6,7]. (ii) The human CRY2 gene is a magnetosensitive molecule. These expression data are complemented by the above-mentioned Drosophila transgenic experiments, which established that the human CRY2 gene is a magnetosensitive molecule [13].
Both the location and functionality of CRY2 in humans are therefore
consistent with a geomagnetic sensing role in humans. (iii) Evidence that melatonin responses to changes in the GMF are transmitted via the eye.
A series of animal experiments provide evidence that the visual system
is involved when melatonin is suppressed owing to magnetic disturbances.
While applied Earth-strength magnetic stimulus significantly reduces
the pineal activity and melatonin expression of rats, acutely blinded
rats reveal no such response [50].
The authors concluded that this suggests a retinal magneto-sensitivity
which may serve to modulate pineal function. However, a pineal
magnetosensitivity cannot be excluded based on such data, as this may
require a light signal as a trigger. (iv) Evidence that melatonin response to changes in the GMF are light-dependent.
Further animal experiments revealed that dim light is necessary to
mediate the effects of the Earth-strength magnetic stimulus on pineal
enzyme activity [49], with other animal studies also revealing interactions of light with the EMF [65]. However, it was revealed that the red light is sufficient to mediate the geomagnetic influence on the circadian system [49].
This finding is perhaps contrary to a role of cryptochrome in mediating
these relationships—a blue-wavelength-specific response would be
expected [6].
However, this could also be representative of an additional layer of
complexity. Magnetoreception in nocturnal newts has been revealed to be
dependent on yellow-red wavelength light, corresponding to
moonlight-dependent magnetoreception [66], and some bird species appear to have multiple magnetic compass receptors operating at different wavelengths of light [6]. In humans, a series of studies have revealed a relationship between light exposure with both geomagnetic [15,16] and anthropogenic magnetic fields [67–69].
The authors argued that the reduction in 6-OHMS excretion associated
with geomagnetic and electromagnetic activity may depend on low levels
of ambient light. However, findings with anthropogenic EMFs remain
extremely controversial, with the majority of studies producing negative
results (see WHO [40] and discussion in the electronic supplementary material). (v) Cryptochrome transgenic experiments. Experiments with Drosophila
revealed that applied magnetic fields influenced their circadian
behaviour, and that this response was again blue-light-dependent [70]. Moreover, cryptochrome-knockout Drosophila
did not show such a response, whereas flies overexpressing cryptochrome
revealed an enhanced response. These experiments therefore provide
initial direct evidence that cryptochrome is involved with transmitting
magnetic field effects to the circadian system. The authors discuss the
results within the context of cryptochrome acting as a secondary
zeitgeber for the circadian system.
(b) The geomagnetic field as a secondary zeitgeber?
Several authors have previously argued that the GMF acts as
a secondary zeitgeber of circadian rhythms, in addition to the primary
synchronizer of the day–night-light cycle. This could operate via
Schumann resonance signals [71] or the reduced variation in the magnetic field at night [42]. The electromagnetic field of 10 Hz exhibits diurnal variations [70], and it has been demonstrated that several organisms—including humans [72], mice [73] and Musca flies [74]—can
have their circadian behaviour influenced or entrained by applied 10 Hz
magnetic fields. However, there are issues with theories of the GMF as a
secondary zeitgeber. There is a questionable utility of a variable
secondary zeitgeber when working alongside a reliable primary
synchronizer (e.g. day-light cycle). Moreover, numerous experiments have
already revealed that when various species [70,72,75,76]
are kept under constant lighting conditions, their circadian rhythms
become free-running and decoupled from the usual 24 h cycle, i.e. they
do not resort to a secondary daily geomagnetic synchronizer in the
absence of the primary synchronizer. For example, the free-running
circadian rhythm of humans was found to be 24.87 h in a natural
geomagnetic environment (whereas under geomagnetically shielded
conditions, it was demonstrated to be a significantly longer length of
25.26 [72]).
Although the experimental environment may be interfering with daily
variations in the natural GMF in some of the above studies, it has been
established that daily variations in the GMF across different animal
facilities are essentially similar and omnipresent [77].
Thus, while the above studies confirm the influence of the GMF on the
circadian system, no study has experimentally established that the
natural GMF can act as a reliable zeitgeber. Instead, an alternative
explanatory framework is proposed.
3. Magnetosense–HPA interactions: two models
(a) A generalized model of migratory-dispersal strategies
Migrating birds display a number of stressful physiological
adaptations to long journeys with low food availability and high
predation—an often nocturnal migration, reduced melatonin amplitude,
increased metabolism, higher body temperature and increased energy
expenditure [78].
However, just as the magnetosense is now thought to be a rather more
common feature of animals than was previously considered, modern
definitions of migration are much more inclusive than past
interpretations [79].
The majority of species are now considered to exhibit life-history
strategies that involve territoriality and home-ranges punctuated by
periodic long-distant dispersals [80],
which can occur for a plethora of reasons (e.g. resource availability,
seasonal excursions, mating etc.) Such migrations represent a stressful
phase mirrored by similar hormonal and behavioural adaptations to bird
navigation, also mediated by the HPA axis [79].
While migrational life-history strategies are under complex control and
poorly understood in birds and other animals, a relationship with
navigational behaviour is implicated [79].
Therefore, in animals using the GMF for navigation, relationships are
expected between the GMF and migrational behaviour. Given the apparent
widespread existence of both long-distance dispersals and the
magnetosense, hypothesized interactions between the GMF, migratory
behaviour and hormonal control are possibly generalizable. In migratory
birds, recent research has established that simulated GMFs influence
hormonal secretion and migrational behaviour, with the elicited
responses being related to specific adaptations of planned long-distant
migrations such as fuelling and metabolic strategies [81,82].
In contrast to these specific strategies, unplanned dispersals in
non-migratory animals might instead be expected to elicit a generalized
stress reaction mediated across the HPA axis in response to unknown
environments with subsequent risks such as low-resource availability and
high predation. It is perhaps noteworthy that the above investigations
on birds represent rare examples of animal experiments where hormonal
responses to simulated MFs are as predicted by theory. Could the
existing data relating changes in the GMF (either GMS or applied MFs) to
hormonal behaviour in animals be appraised under a similar paradigm?
(b) A generalized model of stress responses of sensory systems
It has recently been suggested that in addition to simply
providing compass information, the cryptochrome magnetosense provides a
spherical coordinate system that serves to interface metrics of
distance, direction and spatial position [83].
Magnetodetection could thereby provide a global reference system used
to place local landmark arrays into a register with the local maps of
other areas, to increase the accuracy of a path integration system, to
define directional relationships between landmarks, and also to specify
spatial locations within the landmark array. Such theories are
controversial and to date there is no compelling experimental evidence
(see [83]
for discussion and references). However, observations with mole-rats
have established that the magnetic sense is no different to the other
senses, and is involved in multi-sensory integration with other inputs
(e.g. vestibular, visual, etc.) [84].
Similarly, magnetically responsive activity has been identified in the
nucleus of the basal optic root of birds, where the information is
thought to interact with vestibular inputs [85].
Moreover, gravitational cues—derived from the vestibular system—play an
essential role in cryptochrome-based magnetodetection, providing a
vertical reference used to resolve the ambiguity inherent to a
polarity-independent device [83].
When the vestibular system is exposed to extreme vestibular stimuli,
such as hypogravity, hypergravity, horizontal or angular accelerations,
there is an elicited acute stress response activated across the HPA axis
[86,87],
with the vestibular system being implicated in a variety of
physiological and behavioural functions including modulation of
circadian rhythmicity [86].
Furthermore, there is anatomical evidence for the existence of neuronal
connections between the vestibular system to the SCN [87] and hypothalamic paraventricular nucleus (PVN) [86].
Thus, there exists a clear precedent for hypothesized interactions
between a magnetosense and the HPA axis. Therefore, rather than stress
responses of the magnetosense having evolved as a migrational strategy per se,
as proposed above, such connections could instead be invoked as a
response to extreme or unexpected signals. Such signals could degrade
the proposed magnetodetective components of path integration systems [83]
cause navigational disorientation, and therefore elicit a general
stress response similar to those observed with the vestibular system.
Both of the above models are functionally related,
involving stress responses in relation to novel, extreme or unexpected
signals, and are treated as largely equivalent below. The first model
appraises magnetosense–HPA interactions under classical and
experimentally verified notions of the magnetosense as a primarily
migrational device. However, the magnetosense is thought to have a
maximum resolution of perhaps a few miles [1].
Therefore, in animals with limited dispersal ranges, it is difficult to
envisage a geomagnetic component of dispersal-stress behaviour. In
contrast, the second model appraises interactions of magnetosense–HPA
interactions under more modern (but experimentally unverified)
theoretical models [83],
but as such is more widely generalizable across the animal kingdom. In
fact, both models could coexist in some animals. It is therefore
proposed that information from the magnetosense—known to be integrated
in a hierarchical and complex fashion with the other senses [1–3]—is
used in a series of related hormonal functionalities that are optimized
according to the navigational, migrational or dispersal strategies of
the organism.
(c) Geomagnetic storms as nature's experiment: spoofing the system?
The magnitude of GMS can dwarf the local variation in the GMF [40],
and are known to cause disruptions to human navigational systems.
Similarly, GMS have been suggested to cause navigational disorientation
in the animal kingdom, including bees [88], birds [89] and whales [90].
In a similar manner, experimental evidence has revealed that altered
magnetic field conditions can introduce significant changes in rodent
directional and spatial circuits [84]. According to either of the above models, GMS would introduce signals that are incorrect—yet coherent—to
the magnetosense and associated navigational behaviour. If the
magnetosense also has the above proposed interactions with hormonal
systems, then GMS would subsequently lead to disorientation of hormonal
behaviour across the HPA axis. In fact, the action of GMS on humans have
been previously interpreted as such a generalized stress response [47,91], with correlates largely mirroring those of a stress responses [92],
involving CV pathologies, circadian disturbances, neuropsychiatric
manifestations, immunological responses and apparently widespread
alterations in neuroendocrine markers [47,93–95]
(see electronic supplementary material, table). Therefore, the
‘melatonin hypothesis’ of GMS would be a somewhat limited paradigm, with
GMF–melatonin interactions being just one of a set coordinated hormonal
responses.
In contrast to GMS, the interactions of the magnetosense
with PF-EMFs is likely to be complex, depending on factors such as field
strength, frequency, timing, duration, polarization, lighting
conditions, the relative changes and duration of such sources, in
addition to possible temporal window effects and the age of the
organism. However, as MF frequencies and strength approach the
geomagnetic range and intensity, it might be expected that findings
would become generally more positive, and it is interesting to speculate
how the hypothesized magnetosense–HPA interactions might relate to the
highly controversial literature on the influence of PF-EMFs on
biological systems (see the electronic supplementary material and [62,63]
for further discussion). Nonetheless, there is evidence that the
compass system of at least some animals does react to PF-EMFs—overhead
high-voltage power lines disrupt the normal northsouth alignment of
ruminants with the GMF [96].
(d) Reappraising the existing data under the framework of magnetosense–HPA interactions
It is observed that the apparent sensitivity of melatonin
suppression in response to GMS (becoming significant at around 15–80 nT [15,16,38,39,41,93,97]) mirrors the apparent sensitivity of the compass system (in the range of 10–200 nT [3]).
Furthermore, many previous publications have interpreted findings with
GMS under the assumption that there is some specific component of GMS
that is important (e.g. Schumann resonances [71] or pc1 pulsations [24]),
whereas under the current framework, it is simply the change in the
usual GMF that is sufficient to elicit responses. This is supported by
evidence from laboratory animal studies that it is indeed the change in
applied MF that is important, rather than the main stimulus
itself—removing the stimulus and returning animals to the natural GMF
also produces the observed reductions in melatonin [98].
It should be noted that the GMF is used by migrating
animals in a complex, hierarchical and redundant manner, being of
particularly utility in the absence of other navigational stimuli (e.g.
sun, moon, stars and landmarks) [1–3].
Such hierarchical utilization of sensory input may also be reflected in
the above-proposed magnetosense–HPA interactions, and the effects of
GMS may therefore be particularly acute in the absence of other cues,
e.g. when navigating in new or visually homogenous environments. A
further related situation occurs while sleeping, owing to the absence of
wakeful navigational information. Therefore, when sleeping in a
geomagnetically unfamiliar environment (i.e. representing a dispersal
from the home range), it would be evolutionary rational to attenuate
sleep behaviour. Such speculations are consistent with apparent
night-to-night temporal window effects for the influence of GMS on
melatonin [16,93,98,99].
In contrast, other stress responses may be influenced more immediately
by geomagnetic disturbances, as evidenced by reports of changes to CV
parameters on the day of GMS [29,100],
rather than such effects being purely downstream of melatonin
disturbances (e.g. the day after the GMS). However, complex feedback
between neuroendocrine systems [57]
could, for example, compound impacts on the CV systems, involving both
immediate and melatonin-mediated interactions (e.g. see discussion in
Gmitrov & Gmitrova [29]).
4. Summary of evidence and future evaluation
A role for cryptochrome in transmitting changes in the GMF
to the circadian system is supported by several of the key correlates
used to infer the role of cryptochrome in avian geomagnetic navigation.
However, the evidence relies on only a handful of key papers, findings
will require replicating and extending, issues need to be considered
such as the role of multiple genes (CRY1 and CRY2), and other potential
candidates, especially given the apparent presence of multiple receptors
in other species [6].
Moreover, the hypothesis suggests the use of specific controls for
cryptochrome (e.g. the use of specific wavelengths of light and
oscillating magnetic fields in the low radio-frequency range) and more
sophisticated experimental design (e.g. the use of shielded magnetic
fields and simulated magnetic fields with specific emphasis on
inclination, strength and possible temporal windows effects.) In
contrast to the evidence for cryptochrome, the theoretical framework of
magnetosense–HPA interactions is speculative and currently unsupported
by experimental evidence. However, the existing behavioural paradigm—a
secondary zeitgeber—is of questionable biological utility and
contradicts experimental data. In contrast, the proposed alternative is
consistent with existing notions of life-history theory and of the
interactions between navigational or sensory behaviour and hormonal
responses.
5. Discussion and consequences of the hypothesis
The extensive literature relating geomagnetic and solar
activity to humans is often considered inexplicable and bizarre,
including correlations with crime [19], stock market returns [17], religious experience [101] and revolutions [20].
Detractors of such literature have reasonable grounds for
objection—lacking a rational explanation, such findings are merely
spurious associations, likely to be the result of some unexpected
confounder. However, there is now evidence for a specific biophysical
pathway for these findings, with existing direct and indirect
experimental evidence that cryptochrome is influencing circadian
behaviour in response to magnetic stimuli. A fundamental question
relates to whether cryptochrome could be orientating the circadian and
related hormonal system in space or time, or perhaps even a complex
interaction of both. Either way, the contentious and controversial
associations in the literature are—by some degree—more plausible when
placed upon a reasonable biological narrative. Despite the far-fetched
nature of some of the behavioural and socio-political associations, they
do paint a picture that is coherent when viewed through the framework
of a population-level disruption of circadian rhythms and the subsequent
lost sleep and anxious, stressful days.
Finally, the implications for human health are noted for a
wide variety of disorders associated with geomagnetic activity including
CV disease and psychiatric disorders. Further investigations could
suggest the use of novel therapeutic interventions for diseases
exacerbated by GMS. In Russia—where the effect of GMS have gained much
more widespread institutional acceptance [18,19,57]—a study has already trialled melatonin therapy to prevent the effects of GMS on CV patients, with positive results [58].
However, animal experimental evidence has suggested that the effects of
magnetic activity on the circadian system are light-dependent. Could a
simpler measure—the widespread use of sleep masks—shield at-risk
patients from the negative effects of geomagnetic storms?
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