Summary
Spectral sensitivity of the lateral eyes of the isopodPorcellio scaber (wood louse) and the decapodsCallinectes sapidus (blue crab),Palaemonetes paludosus (Everglades prawn),Orconectes virilis, andO. immunis (crayfish) have been measured between 300 and 660 nm by determining the reciprocal number of photons required to evoke a constant size retinal action potential.
Porcellio is maximally sensitive at 515 nm andCallinectes at 505 nm. Both species have a single pigment system, as spectral sensitivity is unchanged by red light adaptation.
Palaemonetes appears to have a dichromatic color vision. Sensitivity of the dark-adapted eye is dominated by a receptor maximally sensitive at 550–555 nm, but red or yellow adaptation discloses a uv pigment with λmax at about 380 nm. Present evidence suggests the 555 and 380 nm pigments are located in different receptor cells.
Orconectes has peak sensitivity at 565 nm, but under red light adaptation and close to the electroretinographic threshold a second sensitivity maximum appears at 425 nm. As in the prawn, these peaks seem to indicate the presence of a two-receptor color vision system.
The corneas ofOrconectes, Callinectes, andHomarus (lobster) are relatively thick, and microspectrophotometric measurements show near ultraviolet absorption as well as the protein peak at 280 nm. By contrast,Palaemonetes andMusca (housefly), species with near ultraviolet receptors, have thinner corneas which are transparent through the near ultraviolet. The crystalline cone ofPalaemonetes likewise shows no near ultraviolet absorption but a strong protein band at 280 nm.
The scarcity of ultraviolet receptors in the compound eyes of crustacea, in contrast to their common occurrence in insects, is thought to be related to the relative absence of ultraviolet wavelengths in most aquatic environments.
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References
Autrum, H.: The physiological basis of colour vision in honeybees. In: Ciba Foundation Symposium on Physiology and Experimental Psychology of Colour Vision, p. 286–300 (ed.G. E. W. Wolstenholme andJ. Knight). London: A. Churchill, Ltd. 1965.
—, andV. von Zwehl: Die spektrale Empfindlichkeit einzelner Sehzellen des Bienenauges. Z. vergl. Physiol.48, 357–384 (1964).
Bernhard, C. G., W. H. Miller, andA. R. Møller: The insect corneal nipple array. Acta physiol. scand.63, 9–79 (1965).
Buddenbrock, W. von, u.H. Friedrich: Neue Beobachtungen über die kompensatorischen Augenbewegungen und den Farbensinn der Taschenkrabben (Carcinus maenas). Z. vergl. Physiol.19, 747–761 (1933).
Burkhardt, D.: Spectral sensitivity and other response characteristics of single visual cells in the arthropod eye. Symp. Soc. exp. Biol.16, 86–109 (1962).
Chapman, R. M., andA. B. Lall: Electroretinogram characteristics and the spectral mechanisms of the median ocellus and the lateral eye inLimulus polyphemus. J. gen. Physiol.50, 2267–2287 (1967).
Dartnall, H. J. A.: The interpretation of spectral sensitivity curves. Brit. med. Bull.9, 24–30 (1953).
Frisch, K. von: Die Fähigkeit der Bienen, die Sonne durch die Wolken wahrzunehmen. S.-B. bayr. Akad. Wiss., math.-nat. Kl.17, 197–199 (1954).
Goldsmith, T. H.: The nature of the retinal action potential, and the spectral sensitivities of ultraviolet and green receptor systems of the compound eye of the worker honeybee. J. gen. Physiol.43, 775–799 (1960).
—: The color vision of insects. In: Light and life, p. 771–794 (ed.W. D. McElroy andB. Glass). Baltimore: Johns Hopkins Press 1961a.
—: The physiological basis of wavelength discrimination in the eye of the honeybee. In: Sensory communication, p. 357–375 (ed.W. A. Rosenblith). New York: M. I. T. Press and John Wiley & Sons, Inc. 1961b.
—: Do flies have a red receptor ? J. gen. Physiol.49, 265–287 (1965).
—,A. E. Dizon, andH. R. Fernandez: Microspectrophotometry of single crustacean rhabdoms. Biol. Bull.133, 466 (1967) (Abstract).
—: Microspectrophotometry of photoreceptor organelles from the eye of the prawnPalaemonetes. Science161, 468–470 (1968).
—, andH. R. Fernandez: Sensitivity of compound eyes to ultraviolet light. Amer. Zool.6, 150 (1966) (Abstract).
- - The spectral sensitivity of housefly photoreceptors in the mid ultraviolet and the limits of the visible spectrum. J. exptl. Biol. (In press.)
Goldsmith, T. H., andP. R. Ruck: The spectral sensitivities of the dorsal ocelli of cockroaches and honeybees — An electrophysiological study. J. gen. Physiol.41, 1171–1185 (1958).
Hasselmann, E.-M.: Über die relative spektrale Empfindlichkeit von Käfer- und Schmetterlingsaugen bei verschiedenen Helligkeiten. Zool. Jb., Abt. allg. Zool u. Physiol.69, 537–576 (1962).
Horridge, G. A.: Perception of polarization plane, colour and movement in two dimensions by the crab,Carcinus. Z. vergl. Physiol.55, 207–224 (1967).
Hutchinson, G. E.: A treatise on limnology, vol. 1, geography, physics and chemistry, 1015 p. New York: John Wiley & Sons, Inc. 1957.
James, H. R., andE. A. Birge: A laboratory study of the absorption of light by lake waters. Trans. Wisconsin Acad. Sci.31, 1–154 (1938).
Kennedy, D., andM. S. Bruno: The spectral sensitivity of crayfish and lobster vision. J. gen. Physiol.44, 1089–1102 (1961).
—, andR. D. Milkman: Selective light absorption by the lenses of lower vertebrates, and its influence on spectral sensitivity. Biol. Bull.111, 375–386 (1956).
Langer, H.: Über die Pigmentgranula im Facettenauge vonCalliphora erythrocephala. Z. vergl. Physiol.55, 354–377 (1967).
Liebman, P. A., andG. Entine: Sensitive low-light-level microspectrophotometer: detection of photosensitive pigments of retinal cones. J. optical Soc. Amer.54, 1451–1459 (1964).
Stieve, H.: Die spektrale Empfindlichkeitskurve des Auges vonEupagurus bernhardus L. Z. vergl. Physiol.43, 518–525 (1960).
Sverdrup, H. U., M. W. Johnson, andR. H. Fleming: The oceans, their physics, chemistry, and general biology. New York: Prentice-Hall, Inc. 1942.
Wald, G.: Alleged effects of the near ultraviolet on human vision. J. optical Soc. Amer.42, 171–177 (1952).
—: Visual pigments of crayfish. Nature (Lond.)215, 1131–1133 (1967).
—: Single and multiple visual systems in arthropods. J. gen. Physiol.51, 125–156 (1968).
—, andR. Hubbard: Visual pigments of a decapod crustacean: the lobster. Nature (Lond.)180, 278–280 (1957).
—, andJ. M. Krainin: The median eye ofLimulus: an ultraviolet receptor. Proc. nat. Acad. Sci. (Wash.)50, 1011–1017 (1963).
—, andE. B. Seldin: Spectral sensitivity of the common prawn,Palaemonetes vulgaris. J. gen. Physiol.51, 694–700 (1968).
Walther, J. B., andE. Dodt: Die Spektralsensitivität von Insekten-Komplex-augen im Ultraviolet bis 290 mμ. Z. Naturforsch.14b, 273–278 (1959).
Waterman, T. H., H. R. Fernandez, andT. H. Goldsmith: Dichroism of photosensitive pigments in rhabdoms of the crayfishOrconectes. (In preparation 1968.)
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This work was supported in part by USPHS research grant NB 03333 to Yale University and postdoctoral fellowship NB 22,547 to H.R.F.
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Goldsmith, T.H., Fernandez, H.R. Comparative studies of crustacean spectral sensitivity. Z. Vergl. Physiol. 60, 156–175 (1968). https://doi.org/10.1007/BF00878449
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DOI: https://doi.org/10.1007/BF00878449