Rapid Learning of Magnetic Compass Direction by C57BL/6 Mice in a 4-Armed ‘Plus’ Water Maze

Phillips, John B.; Youmans, Paul W.; Muheim, Rachel; Sloan, Kelly; Landler, Lukas; Painter, Michael S.; Anderson, Christopher R.

doi:10.1371/journal.pone.0073112

Cited by 42 publications

(42 citation statements)

References 79 publications

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“…Zebra finches trained to relocate a food reward in the spatial orientation assay using directional magnetic compass information learned the task rapidly, in only three to four training trials (Fig. 1B and Table S1) (33). Birds trained to find the reward at either magnetic north (mN) or magnetic south (mS) were significantly oriented along the trained magnetic compass axis when subsequently tested in the presence of a magnetic field aligned in one of four topographic directions [P < 0.05, confidence interval (CI) test; Fig.…”

Section: Resultsmentioning

confidence: 99%

Polarized light modulates light-dependent magnetic compass orientation in birds

Muheim

Sjöberg

Pinzon-Rodriguez

2016

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

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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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Section: Resultsmentioning

confidence: 99%

Polarized light modulates light-dependent magnetic compass orientation in birds

Muheim

Sjöberg

Pinzon-Rodriguez

2016

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

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“…Animals thus use a light-dependent magnetic compass not only for large-scale migrations but also for small-scale orientation tasks in their familiar environment (e.g. Muheim et al, 2006b;Painter et al, 2013;Phillips et al, 2013; see also Phillips et al, 2010b).…”

Section: Discussionmentioning

confidence: 99%

Zebra finches have a light-dependent magnetic compass similar to migratory birds

Pinzon-Rodriguez

Muheim

2017

Journal of Experimental Biology

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Birds have a light-dependent magnetic compass that provides information about the spatial alignment of the geomagnetic field. It is proposed to be located in the avian retina and mediated by a lightinduced, radical-pair mechanism involving cryptochromes as sensory receptor molecules. To investigate how the behavioural responses of birds under different light spectra match with cryptochromes as the primary magnetoreceptor, we examined the spectral properties of the magnetic compass in zebra finches. We trained birds to relocate a food reward in a spatial orientation task using magnetic compass cues. The birds were well oriented along the trained magnetic compass axis when trained and tested under low-irradiance 521 nm green light. In the presence of a 1.4 MHz radio-frequency electromagnetic (RF)-field, the birds were disoriented, which supports the involvement of radical-pair reactions in the primary magnetoreception process. Birds trained and tested under 638 nm red light showed a weak tendency to orient ∼45 deg clockwise of the trained magnetic direction. Under low-irradiance 460 nm blue light, they tended to orient along the trained magnetic compass axis, but were disoriented under higher irradiance light. Zebra finches trained and tested under high-irradiance 430 nm indigo light were well oriented along the trained magnetic compass axis, but disoriented in the presence of a RF-field. We conclude that magnetic compass responses of zebra finches are similar to those observed in nocturnally migrating birds and agree with cryptochromes as the primary magnetoreceptor, suggesting that light-dependent, radicalpair-mediated magnetoreception is a common property for all birds, including non-migratory species.

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“…Magnetoreception can be involved in many aspects of spatial behaviour: as a compass for local and long-distance movements (Wiltschko and Wiltschko, 1972;Landler et al, 2015;Phillips et al, 2013;Diego-Rasilla et al, 2010;Dommer et al, 2008;Freake et al, 2002) as a source of geographic position information (i.e., a magnetic map Phillips, 1986;Philips et al, 1995;Deutschlander et al, 2012) as a reference that reduces errors in path integration (Kimchi et al, 2004;Philips et al, 2010) and potentially as a spherical coordinate system that helps to encode the organism's immediate surrounding and to incorporate local landmark arrays into a global map of familiar space (Landler et al, 2015;Phillips et al, 2010). Consequently, loss of a magnetic sense could impact both long-distance movements (e.g.…”

Section: Introductionmentioning

confidence: 99%

High levels of maternally transferred mercury disrupt magnetic responses of snapping turtle hatchlings (Chelydra serpentina)

Landler

Painter

Coe

et al. 2017

Environmental Pollution

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a b s t r a c tThe Earth's magnetic field is involved in spatial behaviours ranging from long-distance migration to nongoal directed behaviours, such as spontaneous magnetic alignment (SMA). Mercury is a harmful pollutant most often generated from anthropogenic sources that can bio-accumulate in animal tissue over a lifetime. We compared SMA of hatchling snapping turtles from mothers captured at reference (i.e., low mercury) and mercury contaminated sites. Reference turtles showed radio frequency-dependent SMA along the north-south axis, consistent with previous studies of SMA, while turtles with high levels of maternally inherited mercury failed to show consistent magnetic alignment. In contrast, there was no difference between reference and mercury exposed turtles on standard performance measures. The magnetic field plays an important role in animal orientation behaviour and may also help to integrate spatial information from a variety of sensory modalities. As a consequence, mercury may compromise the performance of turtles in a wide variety of spatial tasks. Future research is needed to determine the threshold for mercury effects on snapping turtles, whether mercury exposure compromises spatial behaviour of adult turtles, and whether mercury has a direct effect on the magnetoreception mechanism(s) that mediate SMA or a more general effect on the nervous system.

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Rapid Learning of Magnetic Compass Direction by C57BL/6 Mice in a 4-Armed ‘Plus’ Water Maze

Cited by 42 publications

References 79 publications

Polarized light modulates light-dependent magnetic compass orientation in birds

Polarized light modulates light-dependent magnetic compass orientation in birds

Zebra finches have a light-dependent magnetic compass similar to migratory birds

High levels of maternally transferred mercury disrupt magnetic responses of snapping turtle hatchlings (Chelydra serpentina)

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