Willi A. Ribi scite author profile

Lateralization of function is a well-known phenomenon in humans. The two hemispheres of the human brain are functionally specialized such that certain cognitive skills, such as language or musical ability, conspecific recognition, and even emotional responses, are mediated by one hemisphere more than the other [1, 2]. Studies over the past 30 years suggest that lateralization occurs in other vertebrate species as well [3-11]. In general, lateralization is observed in different sensory modalities in humans as well as vertebrates, and there are interesting parallels (reviewed in [12]). However, little is known about functional asymmetry in invertebrates [13, 14] and there is only one investigation in insects [15]. Here we show, for the first time, that the honeybee Apis mellifera displays a clear laterality in responding to learned odors. By training honeybees on two different versions of the well-known proboscis extension reflex (PER) paradigm [16, 17], we demonstrate that bees respond to odors better when they are trained through their right antenna. To our knowledge, this is the first demonstration of asymmetrical learning performance in an insect.

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Retinal and optical adaptations for nocturnal vision in the halictid bee Megalopta genalis

Greiner

Ribi

Warrant

2004

Cell and Tissue Research

139

118

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The apposition compound eye of a nocturnal bee, the halictid Megalopta genalis, is described for the first time. Compared to the compound eye of the worker honeybee Apis mellifera and the diurnal halictid bee Lasioglossum leucozonium, the eye of M. genalis shows specific retinal and optical adaptations for vision in dim light. The major anatomical adaptations within the eye of the nocturnal bee are (1) nearly twofold larger ommatidial facets and (2) a 4-5 times wider rhabdom diameter than found in the diurnal bees studied. Optically, the apposition eye of M. genalis is 27 times more sensitive to light than the eyes of the diurnal bees. This increased optical sensitivity represents a clear optical adaptation to low light intensities. Although this unique nocturnal apposition eye has a greatly improved ability to catch light, a 27-fold increase in sensitivity alone cannot account for nocturnal vision at light intensities that are 8 log units dimmer than during daytime. New evidence suggests that additional neuronal spatial summation within the first optic ganglion, the lamina, is involved.

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Eye structure correlates with distinct foraging-bout timing in primitive ants

et al. 2007

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Caste-specific visual adaptations to distinct daily activity schedules in AustralianMyrmeciaants

et al. 2010

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Animals are active at different times of the day and their activity schedules are shaped by competition, time-limited food resources and predators. Different temporal niches provide different light conditions, which affect the quality of visual information available to animals, in particular for navigation. We analysed caste-specific differences in compound eyes and ocelli in four congeneric sympatric species of Myrmecia ants, with emphasis on within-species adaptive flexibility and daily activity rhythms. Each caste has its own lifestyle: workers are exclusively pedestrian; alate females lead a brief life on the wing before becoming pedestrian; alate males lead a life exclusively on the wing. While workers of the four species range from diurnal, diurnal-crepuscular, crepuscular-nocturnal to nocturnal, the activity times of conspecific alates do not match in all cases. Even within a single species, we found eye area, facet numbers, facet sizes, rhabdom diameters and ocelli size to be tuned to the distinct temporal niche each caste occupies. We discuss these visual adaptations in relation to ambient light levels, visual tasks and mode of locomotion.

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Polarisation Vision in Ants, Bees and Wasps

Zeil

Ribi

Narendra

2014

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The organization of honeybee ocelli: Regional specializations and rhabdom arrangements

Ribi

Warrant

Zeil

2011

Arthropod Structure & Development

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Imaging honey bee brain anatomy with micro-X-ray-computed tomography

Ribi

Senden

Sakellariou

et al. 2008

Journal of Neuroscience Methods

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Willi A. Ribi

Nocturnal Vision and Landmark Orientation in a Tropical Halictid Bee

Lateralization of Olfaction in the Honeybee Apis mellifera

Retinal and optical adaptations for nocturnal vision in the halictid bee Megalopta genalis

Eye structure correlates with distinct foraging-bout timing in primitive ants

Caste-specific visual adaptations to distinct daily activity schedules in AustralianMyrmeciaants

Polarisation Vision in Ants, Bees and Wasps

The organization of honeybee ocelli: Regional specializations and rhabdom arrangements

Imaging honey bee brain anatomy with micro-X-ray-computed tomography

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