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Bumblebee visual allometry results in locally improved resolution and globally improved sensitivity

DOI: 10.7554/eLife.40613 DOI Help

Authors: Gavin J. Taylor (Lund University) , Pierre Tichit (Lund University) , Marie D. Schmidt (Lund University) , Andrew J. Bodey (Diamond Light Source) , Christoph Rau (Diamond Light Source) , Emily Baird (Lund University; Stockholm University)
Co-authored by industrial partner: No

Type: Journal Paper
Journal: Elife , VOL 8

State: Published (Approved)
Published: February 2019
Diamond Proposal Number(s): 13848 , 16052

Open Access Open Access

Abstract: The quality of visual information that is available to an animal is limited by the size of its eyes. Differences in eye size can be observed even between closely related individuals, yet we understand little about how this affects vision. Insects are good models for exploring the effects of size on visual systems because many insect species exhibit size polymorphism. Previous work has been limited by difficulties in determining the 3D structure of eyes. We have developed a novel method based on x-ray microtomography to measure the 3D structure of insect eyes and to calculate predictions of their visual capabilities. We used our method to investigate visual allometry in the bumblebee Bombus terrestris and found that size affects specific aspects of vision, including binocular overlap, optical sensitivity, and dorsofrontal visual resolution. This reveals that differential scaling between eye areas provides flexibility that improves the visual capabilities of larger bumblebees.

Journal Keywords: insect; vision; microtomography; bumblebee; visual field

Subject Areas: Biology and Bio-materials
Collaborations: Diamond Manchester

Instruments: I13-2-Diamond Manchester Imaging

elife-40613-v1 (1).pdf