How aquatic water-beetle larvae with small chambered eyes overcome challenges of hunting under water

A particularly unusual visual system exists in the visually guided aquatic predator, the Sunburst Diving Beetle, Thermonectus marmoratus (Coleoptera: Dytiscidae). The question arises: how does this peculiar visual system function? A series of experiments suggests that their principal eyes (E1 and E2...

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Veröffentlicht in:	Journal of Comparative Physiology 2014-11, Vol.200 (11), p.911-922
Hauptverfasser:	Stowasser, Annette, Buschbeck, Elke K
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Sprache:	eng
Schlagworte:	Animal Physiology Animals Biomedical and Life Sciences Coleoptera Coleoptera - anatomy & histology Coleoptera - growth & development Coleoptera - physiology Compound Eye, Arthropod - anatomy & histology Compound Eye, Arthropod - growth & development Compound Eye, Arthropod - physiology Dytiscidae Environment insect larvae Larva - anatomy & histology Larva - physiology Life Sciences Neurosciences photoreceptors predators Predatory Behavior - physiology retina Review Thermonectus Thermonectus marmoratus Water Zoology
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container_title	Journal of Comparative Physiology
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creator	Stowasser, Annette Buschbeck, Elke K
description	A particularly unusual visual system exists in the visually guided aquatic predator, the Sunburst Diving Beetle, Thermonectus marmoratus (Coleoptera: Dytiscidae). The question arises: how does this peculiar visual system function? A series of experiments suggests that their principal eyes (E1 and E2) are highly specialized for hunting. These eyes are tubular and have relatively long focal lengths leading to high image magnification. Their retinae are linear, and are divided into distinct green-sensitive distal and UV and polarization-sensitive proximal portions. Each distal retina, moreover, has many tiers of photoreceptors with rhabdomeres the long axis of which are peculiarly oriented perpendicular to the light path. Based on detailed optical investigations, the lenses of these eyes are bifocal and project focused images onto specific retinal tiers. Behavioral experiments suggest that these larvae approach prey within their eyes’ near-fields, and that they can correctly gauge prey distances even when conventional distance-vision mechanisms are unavailable. In the near-field of these eyes object distance determines which of the many retinal layers receive the best-focused images. This retinal organization could facilitate an unusual distance-vision mechanism. We here summarize past findings and discuss how these eyes allow Thermonectus larvae to be such successful predators.
doi_str_mv	10.1007/s00359-014-0944-9
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subjects	Animal Physiology Animals Biomedical and Life Sciences Coleoptera Coleoptera - anatomy & histology Coleoptera - growth & development Coleoptera - physiology Compound Eye, Arthropod - anatomy & histology Compound Eye, Arthropod - growth & development Compound Eye, Arthropod - physiology Dytiscidae Environment insect larvae Larva - anatomy & histology Larva - physiology Life Sciences Neurosciences photoreceptors predators Predatory Behavior - physiology retina Review Thermonectus Thermonectus marmoratus Water Zoology
title	How aquatic water-beetle larvae with small chambered eyes overcome challenges of hunting under water
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