Browsing by Author "Frank, Tamara M."
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Item Light and vision in the deep-sea benthos: II. Vision in deep-sea crustaceans(The Company of Biologists Ltd, 2012-06-18) Frank, Tamara M.; Johnsen, Sönke; Cronin, Thomas W.Using new collecting techniques with the Johnson-Sea-Link submersible, eight species of deep-sea benthic crustaceans were collected with intact visual systems. Their spectral sensitivities and temporal resolutions were determined shipboard using electroretinography. Useable spectral sensitivity data were obtained from seven species, and in the dark-adapted eyes, the spectral sensitivity peaks were in the blue region of the visible spectrum, ranging from 470 to 497 nm. Under blue chromatic adaptation, a secondary sensitivity peak in the UV portion of the spectrum appeared for two species of anomuran crabs: Eumunida picta (λmax 363 nm) and Gastroptychus spinifer (λmax 383 nm). Wavelength-specific differences in response waveforms under blue chromatic adaptation in these two species suggest that two populations of photoreceptor cells are present. Temporal resolution was determined in all eight species using the maximum critical flicker frequency (CFFmax). The CFFmax for the isopod Booralana tricarinata of 4 Hz proved to be the lowest ever measured using this technique, and suggests that this species is not able to track even slow-moving prey. Both the putative dual visual pigment system in the crabs and the extremely slow eye of the isopod may be adaptations for seeing bioluminescence in the benthic environment.Item A short-wavelength photoreceptor class in a deep-sea shrimp(The Royal Society, 1996-07-22) Cronin, Thomas W.; Frank, Tamara M.In the world of midwater, mesopelagic animals, downwelling sunlight is filtered by the overlying water to a limited waveband centered near 475 nm. Consequently, the visual pigments of most of these species absorb maximally between 450 and 500 nm. The only exceptions occur in some fishes, which have additional visual pigments absorbing at long wavelengths (550-580 nm) matched to their red bioluminescence. We now find that the mesopelagic decapod shrimp Systellaspis debilis has two visual pigments. One of these absorbs maximally in the expected range (λmax = 498 nm), but the other is maximally sensitive at very short wavelengths, approaching the near-ultraviolet (λmax = 410 nm). The discovery of a visual receptor class absorbing at such short wavelengths in a mesopelagic animal suggests that visual systems in the deep sea may be far more diverse, and potentially more complex, than previously suspected.