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Built-in polarizers form part of a compass organ in spiders


Some insects and vertebrates use the pattern of polarized light in the sky as an optical compass1,2,3,4,5. Only a small section of clear sky needs to be visible for bees and ants to obtain a compass bearing for accurate navigation5,6. The receptors involved in the polarization compass are confined to a small part of the retina, and the eyes are built predominantly for other visual tasks7. Here we report the discovery of a unique compass organ in the spider Drassodes cupreus, where a pair of specialized secondary eyes cooperate to analyse skylight polarization. These eyes do not form images, but use a built-in polarization filter to determine precisely the direction of polarization. Measurements using a model eye indicate that the compass organ is best suited for navigation at dusk and dawn. Behavioural experiments show that the spiders are primarily active after sunset and that they use polarization cues to find their way back to the nest after foraging trips. A similar organization of the secondary eyes in several spider families indicates that such compass organs may not be an isolated phenomenon.

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Figure 1: The compass organ of D. cupreus.
Figure 2: Structure of the PM eyes.
Figure 3: Sky-polarization analysis at dusk and dawn.
Figure 4: Layout of the arena used for navigation experiments.


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We thank P. Willander and L. Jonsson for help in finding and identifying the spiders. Information about Gnaphosoids was provided by N. Platnick. R. Wallén provided technical assistance. Financial support came from the Swedish Natural Science Research Council.

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Correspondence to M. Dacke or D.-E. Nilsson.

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Dacke, M., Nilsson, DE., Warrant, E. et al. Built-in polarizers form part of a compass organ in spiders. Nature 401, 470–473 (1999).

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