Magnetic compass orientation in the blind mole rat Spalax ehrenbergi

2001 ◽  
Vol 204 (4) ◽  
pp. 751-758 ◽  
Author(s):  
T. Kimchi ◽  
J. Terkel
Keyword(s):  
Magnetic Field ◽  
Magnetic Compass ◽  
Food Store ◽  
Earth’S Magnetic Field ◽  
Compass Orientation ◽  
Spalax Ehrenbergi ◽  
Mole Rat ◽  
Earth's Magnetic Field ◽  
Magnetic Compass Orientation ◽  
Directional Preference

The blind mole rat Spalax ehrenbergi is a solitary, subterranean rodent that digs and inhabits a system of branching tunnels, with no above-ground exits, which it never leaves unless forced to. To survive, the mole rat must be able to orient efficiently in its tunnel system. The sensory channels available for spatial orientation in the subterranean environment are restricted in comparison with those existing above ground. This study examined the possibility that the mole rat is able to perceive and use the earth's magnetic field to orient in space. Experiments were performed using a device constructed from a pair of electromagnetic ‘Helmholtz coils’, which create a magnetic field whose direction and strength can be altered. In the first experiment, we tested a group of mole rats (N=33) in an eight-armed maze under the earth's natural magnetic field to determine whether they have directional preferences for the location of their sleeping nest, food chamber and toilet site. A second group of mole rats (N=30) was tested for their directional preference after the earth's magnetic field had been experimentally shifted by 180 degrees. We found that the first group exhibited a significant preference (P<0.001) to build both their sleeping nest and their food store in the southern sector of the maze, whereas the second group shifted the location of their nests (P<0.01) and food store (P<0.05), to the northern sector of the maze, corresponding to the shift in the magnetic field. In the second experiment, we tested whether the magnetic compass orientation found in the first experiment depends on a light stimulus by testing a group of mole rats in the eight-armed maze under total darkness. No significant difference in directional preference between light and dark test conditions was observed. It can be concluded, therefore, that, in contrast to some amphibians and birds, magnetic compass orientation in the mole rat is independent of light stimulation. In the third experiment, we examined whether mole rats (N=24) use the earth's magnetic field as a compass cue to orient in a labyrinth. In the first stage (trials 1–13), the animals were trained to reach a goal box at the end of a complex labyrinth until all individuals had learned the task. In the second stage (trial 14), half the trained mole rats underwent another labyrinth trial under the earth's natural magnetic field, while the other half were tested under a magnetic field shifted by 180 degrees. We found a significant decrease (P<0.001) in performance of the mole rats tested under the shifted magnetic field compared with the group tested under the natural magnetic field. The findings from these experiments prove that the mole rat is able to perceive and use the earth's magnetic field to orient in space.

Lateralisation of magnetic compass orientation in silvereyes, Zosterops lateralis

2003 ◽  
Vol 51 (6) ◽  
pp. 597 ◽  
Author(s):  
Wolfgang Wiltschko ◽  
Ursula Munro ◽  
Hugh Ford ◽  
Roswitha Wiltschko
Keyword(s):  
Geomagnetic Field ◽  
Magnetic Compass ◽  
Compass Orientation ◽  
Directional Information ◽  
Zosterops Lateralis ◽  
Magnetic Compass Orientation ◽  
Directional Preference ◽  
The Right ◽  
The Brain ◽  
The Magnetic Field

The ability of migratory silvereyes to orient was tested in the geomagnetic field with one eye covered. Silvereyes using only their right eye were able to orient in migratory direction just as well as birds using both eyes. Using only their left eye, however, the birds did not show a significant directional preference. These data indicate that directional information from the magnetic field is mediated almost exclusively by the right eye and processed by the left hemisphere of the brain. Together with corresponding findings from European robins and indications for a similar phenomenon in homing pigeons, they suggest that a strong lateralisation of the magnetic compass is widespread among birds.

scholarly journals Eyes are essential for magnetoreception in a mammal

2020 ◽  
Author(s):  
Kai R. Caspar ◽  
Katrin Moldenhauer ◽  
Regina E. Moritz ◽  
E. Pascal Malkemper ◽  
Sabine Begall
Keyword(s):  
Magnetic Field ◽  
Magnetic Orientation ◽  
Orientation Behavior ◽  
Significant Preference ◽  
Compass Orientation ◽  
Subterranean Rodent ◽  
Magnetic Parameters ◽  
Mole Rat ◽  
Magnetic Compass Orientation ◽  
Magnetic Sense

AbstractSeveral groups of mammals use the Earth’s magnetic field for orientation, but their magnetosensory organ remains unknown. The Ansell’s mole-rat (Fukomys anselli) is a subterranean rodent with innate magnetic orientation behavior. Previous studies proposed that its magnetoreceptors are located in the eye. To test this hypothesis, we assessed magnetic orientation in enucleated mole-rats.Initially, we demonstrate that enucleation of mole-rats does not lead to changes in routine behaviors. We then studied magnetic compass orientation by employing a well-established nest building assay. To ensure that directional responses were based on magnetic parameters, we tested animals under four magnetic field alignments. In line with previous studies, control animals exhibited a significant preference to build nests in magnetic south-east. In contrast, enucleated mole-rats built nests in random magnetic orientations, suggesting an impairment of their magnetic sense. The results provide robust support for the hypothesis that mole-rats perceive magnetic fields with their minute eyes.

scholarly journals GEOMAGNETIC ORIENTATION OF LOGGERHEAD SEA TURTLES: EVIDENCE FOR AN INCLINATION COMPASS

1993 ◽  
Vol 182 (1) ◽  
pp. 1-10 ◽  
Author(s):  
P. Light ◽  
M. Salmon ◽  
K. J. Lohmann
Keyword(s):  
Magnetic Field ◽  
Field Component ◽  
Sea Turtles ◽  
Magnetic Compass ◽  
Magnetic Field Component ◽  
Vertical Magnetic Field ◽  
Earth’S Magnetic Field ◽  
Loggerhead Sea Turtles ◽  
Earth's Magnetic Field ◽  
Inclination Compass

Recent experiments have demonstrated that hatchling loggerhead sea turtles can orient using the earth's magnetic field. To investigate the functional characteristics of the loggerhead magnetic compass, we tested the orientation of hatchlings tethered inside a circular arena surrounded by a coil system that could be used to reverse the vertical and horizontal components of the ambient field. Hatchlings tested in darkness in the earth's magnetic field were significantly oriented in an eastward direction. Inverting the vertical magnetic field component resulted in an approximate reversal of orientation direction, whereas reversing both the vertical and horizontal components together did not. The hatchlings failed to orient in a horizontal field of earth-strength intensity. These results provide evidence that the magnetic compass of loggerheads is an inclination (axial) compass, functionally similar to that of birds.

scholarly journals Eyes are essential for magnetoreception in a mammal

2020 ◽  
Vol 17 (170) ◽  
pp. 20200513
Author(s):  
Kai R. Caspar ◽  
Katrin Moldenhauer ◽  
Regina E. Moritz ◽  
Pavel Němec ◽  
E. Pascal Malkemper ◽  
...  
Keyword(s):  
Magnetic Field ◽  
Surgical Removal ◽  
Magnetic Orientation ◽  
Significant Preference ◽  
Compass Orientation ◽  
Subterranean Rodent ◽  
Orientation Behaviour ◽  
Mole Rat ◽  
Magnetic Compass Orientation ◽  
Magnetic Sense

Several groups of mammals use the Earth's magnetic field for orientation, but their magnetosensory organ remains unknown. The Ansell's mole-rat ( Fukomys anselli , Bathyergidae, Rodentia) is a microphthalmic subterranean rodent with innate magnetic orientation behaviour. Previous studies on this species proposed that its magnetoreceptors are located in the eye. To test this hypothesis, we assessed magnetic orientation in mole-rats after the surgical removal of their eyes compared to untreated controls. Initially, we demonstrate that this enucleation does not lead to changes in routine behaviours, including locomotion, feeding and socializing. We then studied magnetic compass orientation by employing a well-established nest-building assay under four magnetic field alignments. In line with previous studies, control animals exhibited a significant preference to build nests in magnetic southeast. By contrast, enucleated mole-rats built nests in random magnetic orientations, suggesting an impairment of their magnetic sense. The results provide robust support for the hypothesis that mole-rats perceive magnetic fields with their minute eyes, probably relying on magnetite-based receptors in the cornea.

scholarly journals Avian magnetic compass can be tuned to anomalously low magnetic intensities

2013 ◽  
Vol 280 (1763) ◽  
pp. 20130853 ◽  
Author(s):  
Michael Winklhofer ◽  
Evelyn Dylda ◽  
Peter Thalau ◽  
Wolfgang Wiltschko ◽  
Roswitha Wiltschko
Keyword(s):  
Magnetic Field ◽  
Exposure Time ◽  
Geomagnetic Field ◽  
Magnetic Compass ◽  
Radical Pair Mechanism ◽  
Compass Orientation ◽  
Directional Information ◽  
Total Exposure Time ◽  
Magnetic Compass Orientation ◽  
Local Intensity

The avian magnetic compass works in a fairly narrow functional window around the intensity of the local geomagnetic field, but adjusts to intensities outside this range when birds experience these new intensities for a certain time. In the past, the geomagnetic field has often been much weaker than at present. To find out whether birds can obtain directional information from a weak magnetic field, we studied spontaneous orientation preferences of migratory robins in a 4 µT field (i.e. a field of less than 10 per cent of the local intensity of 47 µT). Birds can adjust to this low intensity: they turned out to be disoriented under 4 µT after a pre-exposure time of 8 h to 4 µT, but were able to orient in this field after a total exposure time of 17 h. This demonstrates a considerable plasticity of the avian magnetic compass. Orientation in the 4 µT field was not affected by local anaesthesia of the upper beak, but was disrupted by a radiofrequency magnetic field of 1.315 MHz, 480 nT, suggesting that a radical-pair mechanism still provides the directional information in the low magnetic field. This is in agreement with the idea that the avian magnetic compass may have developed already in the Mesozoic in the common ancestor of modern birds.

scholarly journals Magnetic Compass Orientation in a Palaearctic–Indian Night Migrant, the Red-Headed Bunting

Animals ◽  
2021 ◽  
Vol 11 (6) ◽  
pp. 1541
Author(s):  
Tushar Tyagi ◽  
Sanjay Kumar Bhardwaj
Keyword(s):  
Magnetic Field ◽  
Northern Hemisphere ◽  
Spring Migration ◽  
Magnetic Compass ◽  
Day Length ◽  
Compass Orientation ◽  
Long Distance ◽  
Specific Direction ◽  
Magnetic Compass Orientation ◽  
Overcast Sky

Red-headed buntings (Emberiza bruniceps) perform long-distance migrations within their southerly overwintering grounds and breeding areas in the northern hemisphere. Long-distance migration demands essential orientation mechanisms. The earth’s magnetic field, celestial cues, and memorization of geographical cues en route provide birds with compass knowledge during migration. Birds were tested during spring migration for orientation under natural clear skies, simulated overcast skies at natural day length and temperature, simulated overcast at 22 °C and 38 °C temperatures, and in the deflected (−120°) magnetic field. Under clear skies, the red-headed buntings were oriented NNW (north–northwest); simulated overcast testing resulted in a northerly mean direction at local temperatures as well as at 22 °C and 38 °C. The buntings reacted strongly in favor of the rotated magnetic field under the simulated overcast sky, demonstrating the use of a magnetic compass for migrating in a specific direction.

The Royal Society and the deviation of the compass

1977 ◽  
Vol 31 (2) ◽  
pp. 297-309 ◽  
Keyword(s):  
Magnetic Field ◽  
Mathematical Analysis ◽  
Royal Society ◽  
Permanent Magnets ◽  
Tentative Method ◽  
Magnetic Compass ◽  
Earth’S Magnetic Field ◽  
Magnetic Action ◽  
Earth's Magnetic Field

THE compensation of the effect of the ship’s magnetism on a magnetic compass placed on board is effected by means of ‘correctors’ in the form of permanent magnets (which collectively neutralize the permanent magnetic action of the ship on the compass needle), and soft iron correctors (which collectively neutralize those components of the ship’s magnetism resulting from induction by the Earth’s magnetic field). The mathematical analysis of the effect of ship magnetism on a magnetic compass is not without difficulty; but, fortunately for the navigator, the process of compensation by a simple tentative method, first suggested by Airy in 1839 and perfected by Thomson in the late 1870s, is relatively easy.

scholarly journals Hall Effect Sensor for Animal Geomagnetic Navigation

2021 ◽  
Vol 4 (2) ◽  
Author(s):  
Sachs F
Keyword(s):  
Magnetic Field ◽  
Hall Effect ◽  
Magnetic Compass ◽  
Earth’S Magnetic Field ◽  
Human Navigation ◽  
Hall Effect Sensor ◽  
Navigation Tool ◽  
Earth's Magnetic Field

The magnetic compass has been a valuable human navigation tool for hundreds of years. Yet animals are known to align themselves with the earth’s magnetic field without using ferrimagnets.

scholarly journals Polarized light modulates light-dependent magnetic compass orientation in birds

2016 ◽  
Vol 113 (6) ◽  
pp. 1654-1659 ◽  
Author(s):  
Rachel Muheim ◽  
Sissel Sjöberg ◽  
Atticus Pinzon-Rodriguez
Keyword(s):  
Magnetic Field ◽  
Radical Pair ◽  
Polarized Light ◽  
Magnetic Compass ◽  
Radical Pair Mechanism ◽  
Magnetic Field Effects ◽  
Compass Orientation ◽  
Magnetic Compass Orientation ◽  
Avian Retina ◽  
The Magnetic Field

Magnetoreception of the light-dependent magnetic compass in birds is suggested to be mediated by a radical-pair mechanism taking place in the avian retina. Biophysical models on magnetic field effects on radical pairs generally assume that the light activating the magnetoreceptor molecules is nondirectional and unpolarized, and that light absorption is isotropic. However, natural skylight enters the avian retina unidirectionally, through the cornea and the lens, and is often partially polarized. In addition, cryptochromes, the putative magnetoreceptor molecules, absorb light anisotropically, i.e., they preferentially absorb light of a specific direction and polarization, implying that the light-dependent magnetic compass is intrinsically polarization sensitive. To test putative interactions between the avian magnetic compass and polarized light, we developed a spatial orientation assay and trained zebra finches to magnetic and/or overhead polarized light cues in a four-arm “plus” maze. The birds did not use overhead polarized light near the zenith for sky compass orientation. Instead, overhead polarized light modulated light-dependent magnetic compass orientation, i.e., how the birds perceive the magnetic field. Birds were well oriented when tested with the polarized light axis aligned parallel to the magnetic field. When the polarized light axis was aligned perpendicular to the magnetic field, the birds became disoriented. These findings are the first behavioral evidence to our knowledge for a direct interaction between polarized light and the light-dependent magnetic compass in an animal. They reveal a fundamentally new property of the radical pair-based magnetoreceptor with key implications for how birds and other animals perceive the Earth’s magnetic field.

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