Abstract
The behavioral sensitivities of five species of deep-sea crustaceans (order Decapoda: Acanthephyra curtirostris, A. smithi, Notostomus gibbosus, Janicella spinacauda and Oplophorus gracilirostris) to near-UV and blue-green light were studied during a research cruise off the coast of Hawaii in 1993. Two of the five species have electrophysiologically-measured spectral sensitivity peaks at 400 and 500 nm, while the remaining three species have a single sensitivity peak at 490 to 500 nm. In the current study, behavioral mean threshold sensitivities (defined as the lowest irradiance change to which the shrimp would give a behavioral response) were determined for tethered specimens of each species at two wavelengths, 400 and 500 nm. The mean behavioral threshold sensitivities of the two species with putative dual visual-pigment systems were approximately the same to near-UV and blue-green light, while the other three species were significantly less sensitive to near-UV vs blue-green light. Results from these experiments indicate that (1) behavioral information obtained from tethered shrimp accurately reflects their spectral sensitivity, and (2) the sensitivity of the putative dichromats to near-UV light is sufficiently low to detect calculated levels of near-UV light remaining in the down-welling field at their daytime depth of 600 m. Possible functions of this high sensitivity to short wavelength light are discussed.
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Childress JJ, Barnes AT, Quetin LB, Robison BH (1977) Thermally protecting cod ends for the recovery of living deep-sea animals. Deep-Sea Res 25:419–422
Childress JJ, Price MH (1978) Growth rate of the bathypelagic crustacean Gnathophausia ingens. I. Dimensional growth and population structure. Mar Biol 50:47–62
Clarke WD (1963) Function of bioluminescence in mesopelagic organisms. Nature, Lond 198:1244–1246
Cowles DL, Childress JJ, Wells ME (1991) Metabolic rates of mid-water crustaceans as a function of depth of occurrence off the Hawaiian Islands: food availability as a selective factor. Mar Biol 110:75–83
Cronin TW, (1986) Optical design and evolutionary adaptations in crustacean compound eyes. J. Crustacean Biol 6:1–23
Daan N, Ringelberg J (1969) Further studies on the positive and negative phototactic reaction of Daphnia magna Strans. Neth J Zool 19:525–545
Denton EJ, Warren FJ (1957) The photosensitive pigments in the retinae of deep-sea fish. Nature, Lond 178:1059
Douglas RH, Thorpe A (1992) Short-wave absorbing pigments in the ocular lenses of deep-sea fishes. J mar biol Ass UK 72:93–112
Forward RB Jr (1987) Comparative study of crustacean larval photoresponses. Mar Biol 94:589–595
Forward RB Jr, Cronin TW, Stearns DE (1984) Control of diel vertical migration: photoresponses of a larval crustacean. Limnol Oceanogr 29:145–154
Frank TM, Case JF (1988) Visual spectral sensitivities of bioluminescent deep-sea crustaceans. Biol Bull mar biol Lab, Woods Hole 175:261–273
Frank TM, Widder EA (1994) Evidence for behavioral sensitivity to near-UV light in the deep-sea crustacean Systellaspis debilis. Mar Biol 118:279–284
Herring PJ (1983) The spectral characteristics of luminous marine organisms. Proc R Soc (Ser B) 220:183–217
Herring PJ (1990) Bioluminescent communication in the sea. In: Herring PJ et al (eds) Light and life in the sea. Cambridge University Press, Cambridge, pp 245–265
Hiller-Adams P, Widder EA, Case JF (1988) The visual pigments of four deep-sea crustacean species. J comp Physiol A163:63–72
Latz MI, Frank TM, Case JF (1988) Spectral composition of bioluminescence of epipelagic organisms from the Sargasso Sea. Mar Biol 98:441–446
Locket NA (1977) Adaptations to the deep-sea envirnoment. In: Crescitelli F (ed) Handbook of sensory physiology. Vol. VII/5. The visual system in vertebrates. Springer Verlag, Berlin, pp 68–192
Loew ER (1976) Light, and photoreceptor degeneration in the Norway lobster, Nephrops norvegicus. Proc R Soc (Ser B) 193:31–44
Munk O (1966) Ocular anatomy of some deep-sea teleosts. Dana Rep 70:1–62
Muntz WRA (1976) On yellow lenses in mesopelagic animals. J mar Biol Ass UK 56:963–976
Muntz WRA (1983) Bioluminescence and vision. In: Macdonald AG, Priede IG (eds) Experimental biology at sea. Academic Press, London, pp 217–238
Partridge JC, Archer SN, Lythgoe JN (1988) Visual pigments in the individual rods of deep-sea fishes. J comp Physiol A162:543–550
Roe HSJ (1984) The diel migrations and distributions within a mesopelagic community in the north east Atlantic. 2. Vertical migrations and feeding of mysids and decapod crustacea. Prog Oceanogr 13:269–318
Stearns DE, Forward RB Jr (1984 a) Photosensitivity of the calanoid copepod Acartia tonsa. Mar Biol 82:85–89
Stearns DE, Forward RB Jr (1984 b) Copepod photobehavior in a simulated natural light environment and its relation to nocturnal vertical migration. Mar Biol 82:91–100
Strickler, JR (1969) Experimentell-ökologische Untersuchungen über die Vertikalwanderung planktischer Crustaceen. Ph. D. thesis. Edigenössische Technische Hochschule, Zürich
Swift MC, Forward RB Jr (1988) Absolute light intensity vs. rate of relative change in light intensity: the role of light in the vertical migration of Chaoborus punctipennis larvae. Bull mar Sci 43: 604–619
Wald G, Rayport S (1977) Vision in annelid worms. Science, NY 196:1434–1439
Widder EA, Latz MI, Case JF (1983) Marine bioluminescence spectra measured with an optical multichannel detection system. Biol Bull mar biol Lab, Woods Hole, 165:791–810
Zieman DA (1975) Patterns of vertical distribution, vertical migration, and reproduction in the Hawaiian mesopelagic shrimp of the family Oplophoridae. Ph. D. thesis. University of Hawaii, Honolulu
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Communicated by N. H. Marcus, Tallahassee
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Frank, T.M., Widder, E.A. Comparative study of behavioral-sensitivity thresholds to near-UV and blue-green light in deep-sea crustaceans. Marine Biology 121, 229–235 (1994). https://doi.org/10.1007/BF00346730
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DOI: https://doi.org/10.1007/BF00346730