Extraocular magnetic compass in newts

Deutschlander, Mark E.; Borland, S. Chris; Phillips, John B.

doi:10.1038/22450

Cited by 100 publications

(67 citation statements)

References 6 publications

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“…In mole rats, the magnetic compass appears to be mediated by a mechanism involving permanently magnetic material, presumed to be particles of biogenic magnetite (Kimchi & Terkel, 2001;Marhold, Burda, Kreilos, & Wiltschko, 1997;. In contrast, the magnetic compass of songbirds and amphibians is light dependent (Deutschlander, Borland, & Phillips, 1999;Freake & Phillips, 2005;Phillips & Borland, 1992;W. Wiltschko & R. Wiltschko, 2005) and sensitive to low-level radio frequency fields (Phillips & Freake, 2006;Ritz et al, 2004), consistent with a magnetoreception mechanism involving a light-sensitive biochemical reaction (Ritz et al, 2000).…”

Section: Discussionmentioning

confidence: 99%

Magnetic compass orientation in C57BL/6J mice

Muheim

Edgar

Sloan

et al. 2006

Learning & Behavior

109

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Section: Discussionmentioning

confidence: 99%

Magnetic compass orientation in C57BL/6J mice

Muheim

Edgar

Sloan

et al. 2006

Learning & Behavior

109

View full text Add to dashboard Cite

“…photoreceptors, the LDMC in insects (Phillips and Sayeed, 1993;Vacha et al, 2008b), amphibians (Phillips and Borland 1992a;Deutschlander et al, 1999a;Freake and Phillips, 2005) and, possibly, birds (Muheim et al, 2002;Wiltschko et al, 2010) share functional properties (i.e. light-dependent 90deg rotations in the direction of magnetic compass orientation) that appear to result, at least in part, from an antagonistic interaction of short-and longwavelength inputs (Phillips and Borland, 1992a;Deutschlander et al, 1999b;Phillips et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

A behavioral perspective on the biophysics of the light-dependent magnetic compass: a link between directional and spatial perception?

Phillips

Muheim

Jorge

2010

Journal of Experimental Biology

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Summary In terrestrial organisms, sensitivity to the Earth's magnetic field is mediated by at least two different magnetoreception mechanisms, one involving biogenic ferromagnetic crystals (magnetite/maghemite) and the second involving a photo-induced biochemical reaction that forms long-lasting, spin-coordinated, radical pair intermediates. In some vertebrate groups (amphibians and birds), both mechanisms are present; a light-dependent mechanism provides a directional sense or ‘compass’, and a non-light-dependent mechanism underlies a geographical-position sense or ‘map’. Evidence that both magnetite- and radical pair-based mechanisms are present in the same organisms raises a number of interesting questions. Why has natural selection produced magnetic sensors utilizing two distinct biophysical mechanisms? And, in particular, why has natural selection produced a compass mechanism based on a light-dependent radical pair mechanism (RPM) when a magnetite-based receptor is well suited to perform this function? Answers to these questions depend, to a large degree, on how the properties of the RPM, viewed from a neuroethological rather than a biophysical perspective, differ from those of a magnetite-based magnetic compass. The RPM is expected to produce a light-dependent, 3-D pattern of response that is axially symmetrical and, in some groups of animals, may be perceived as a pattern of light intensity and/or color superimposed on the visual surroundings. We suggest that the light-dependent magnetic compass may serve not only as a source of directional information but also provide a spherical coordinate system that helps to interface metrics of distance, direction and spatial position.

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“…Like the sun azimuth and associated skylight patterns that allow hymenopterans to path integrate over considerable distances with an amazing accuracy (22)(23)(24), the geomagnetic field represents a constant general directional reference, which can be used in any habitat with equal efficiency (31). Furthermore, because the geomagnetic field can be perceived irrespective of light (36), it has a crucial evolutionary advantage for species that orient in the dark, as is the case for the Spalax mole rat. In light of our current knowledge, we believe that other subterranean species, and possibly also surface-dwelling nocturnal animals, may have evolved the same highly accurate navigation system.…”

Section: Resultsmentioning

confidence: 99%

A subterranean mammal uses the magnetic compass for path integration

Kimchi

Etienne²,

Terkel³

2004

Proc. Natl. Acad. Sci. U.S.A.

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Path integration allows animals to navigate without landmarks by continuously processing signals generated through locomotion. Insects such as bees and ants have evolved an accurate path integration system, assessing and coding rotations with the help of a general directional reference, the sun azimuth. In mammals, by contrast, this process can take place through purely idiothetic (mainly proprioceptive and vestibular) signals. However, without any stable external reference for measuring direction, path integration is highly affected by cumulative errors and thus has been considered so far as valid only for short-distance navigation. Here we show through two path integration experiments (homing and shortcut finding) that the blind mole rat assesses direction both through internal signals and by estimating its heading in relation to the earth's magnetic field. Further, it is shown that the greater the circumvolution and length of the traveled path, the more the animal relies on the geomagnetic field. This path integration system strongly reduces the accumulation of errors due to inaccuracies in the estimation of rotations and thus allows the mole rat to navigate efficiently in darkness, without the help of any landmark, over both short and long distances.

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Extraocular magnetic compass in newts

Cited by 100 publications

References 6 publications

Magnetic compass orientation in C57BL/6J mice

Magnetic compass orientation in C57BL/6J mice

A behavioral perspective on the biophysics of the light-dependent magnetic compass: a link between directional and spatial perception?

A subterranean mammal uses the magnetic compass for path integration

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