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Patterns of pigmentation in the eye lens of the deep-sea hatchetfish,Argyropelecus affinis Garman

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Summary

The present study is a morphological, biochemical and spectrophotometric characterization of the eye lens pigmentation in 45 specimens (11–88 mm in standard length) of the deep-sea hatchetfish,Argyropelecus affinis (Stomiiformes: Sternoptychidae). For comparison, we also examined available lenses of other members of the family Sternoptychidae, including three other species of the genusArgyropelecus, and two species of the genusSternoptyx. Lens pigmentation was observed in all specimens ofArgyropelecus spp. larger than about 36 mm in standard length, but was absent in allArgyropelecus spp. individuals less than 36 mm. However, lens pigmentation was not observed inSternoptyx specimens of any size. Detailed studies ofA. affinis indicated that (1) at 36 mm the nascent lens fiber cells, which are continually laid down over preexisting, unpigmented cells, begin incorporating pigment, and (2) the pigment concentration increases steadily as pigmented cells are added during lens growth. Spectrophotometric and biochemical data suggested that the pigment is a carotenoprotein complex, the carotenoid-like chromophore being strongly associated with a specific soluble lens protein, alpha crystallin. While the lens coloration in these fishes is age-related, analyses of the retinal visual pigment revealed no concomitant age-related change in the peak wavelength of retinal sensitivity in these fishes. Our data on the spectral absorbance of the lens and visual pigment of these fishes suggest that the lens pigmentation acts as a short-wave filter to improve acuity of the visual system.

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References

  • Appleby SJ, Muntz WRA (1979) Occesable yellow corneas in Tetraodontidae. J Exp Biol 83:249–259

    Google Scholar 

  • Baird RC (1971) The systematics, distribution, and zoogeography of marine hatchetfishes (Family Sternoptychidae). Bull Mus Comp Zool 142:1–128

    Google Scholar 

  • Bando M, Nakajima A, Satoh K (1981) Spectroscopic estimation of 3-OH L kynurenine O-B-glucoside in the human lens. J Biochem 89:103–109

    Google Scholar 

  • Berbers GAM, Boerman OC, Bloemendal H, Jong WW de (1982) Primary gene products of bovine beta-crystallin and reassociation behavior of its aggregates. Eur J Biochem 128:495–502

    Google Scholar 

  • Cheesman DF, Lee WL, Zagalsky PF (1967) Carotenoproteins in invertebrates. Biol Rev Cambridge Phil Soc 42:131–160

    Google Scholar 

  • Cooper GF, Robson JG (1969a) The yellow colour of the lens of the grey squirrel. J Physiol 203:403–410

    Google Scholar 

  • Cooper GF, Robson JG (1969b) The yellow colour of the lens of man and other primates. J Physiol 203:411–417

    Google Scholar 

  • Dartnall HJA (1957) The visual pigments. Methuen, London

    Google Scholar 

  • Dartnall HJA (1972) Photochemistry. In: Dartnall HJA (ed) Photochemistry of vision. (Handbook of sensory physiology, vol VII/1.) Springer, Berlin Heidelberg New York, pp 122–145

    Google Scholar 

  • Denton EJ, Herring PJ, Widder EA, Latz MA, Case JF (1985) The roles of filters in the photophores of oceanic animals and their relation to vision in the oceanic environment. Proc R Soc Lond B 225:63–97

    Google Scholar 

  • de Jong WW (1981) Evolution of lens and crystallins. In: Bloemendal H (ed) Molecular and cellular biology of the eye lens. John Wiley, New York Chichester Brisbane Toronto, pp 221–278

    Google Scholar 

  • Heinermann PH (1984) Yellow intraocular filters in fishes. Exp Biol 43:127–147

    Google Scholar 

  • Hoenders HJ, Bloemendal H (1981) Aging of lens proteins. In: Bloemendal H (ed) Molecular and cellular biology of the eye lens. John Wiley, New York Chichester Brisbane Toronto, pp 279–326

    Google Scholar 

  • Kampa EM, Boden BP (1957) Light generation in a sonic scattering layer. Deep-Sea Res 4:73–92

    Google Scholar 

  • Kondrashev SL, Gamburtzeva AG, Gnjubkina VP, Orlov OJ, My PT (1986) Coloration of corneas offish. A list of species. Vision Res 26:287–290

    Google Scholar 

  • Laemmli UK (1970) Cleavage of structural proteins during the assembly of the head of bacterial phage T4. Nature 227:680–685

    Google Scholar 

  • Ludvigh E, McCarthy EF (1938) Absorption of visible light by the refractive media of the human eye. Arch Ophthalmol 20:37–51

    Google Scholar 

  • Lythgoe JN (1979) The ecology of vision. Clarendon Press, Oxford, p 244

    Google Scholar 

  • Manski W, Malinowski K (1978) The evolutionary sequence and quantities of different antigenic determinants of calf lens alpha crystallin. Immunochemistry 15:781–786

    Google Scholar 

  • McEwen WK (1959) The yellow lens pigment of human lenses. Am J Ophthalmol 47:144–146

    Google Scholar 

  • McFall-Ngai MJ, Ding LL, Takemoto LJ, Horwitz J (1985) Spatial and temporal mapping of the age-related changes in human lens crystallins. Exp Eye Res 41:745–758

    Google Scholar 

  • Moreland JD, Lythgoe JN (1968) Yellow corneas in fishes. Vision Res 8:1377–1380

    Google Scholar 

  • Muntz WRA (1972) Inert absorbing and reflecting pigments. In: Dartnall HJA (ed) Photochemistry of vision. (Handbook of sensory physiology, vol VII/1.) Springer, Berlin Heidelberg New York, pp 529–565

    Google Scholar 

  • Muntz WRA (1976) On yellow lenses in mesopelagic animals. J Mar Biol Assoc UK 56:963–976

    Google Scholar 

  • Nicol JAC (1962) Animal luminescence. Adv Comp Physiol Biochem 1:217–273

    Google Scholar 

  • Oakley BR, Kirsch DR, Morris NR (1980) A simplified ultrasensitive silver stain for detecting proteins in polyacrylamide gels. Anal Biochem 105:361–363

    Google Scholar 

  • Orlov OY, Gamburtsera AG (1976) Changeable colouration of cornea in the fishHexagrammus octogrammus. Nature 263:405–407

    Google Scholar 

  • Somiya H (1976) Functional significance of the yellow lens in the eyes ofArgyropelecus affinis. Mar Biol 34:93–99

    Google Scholar 

  • Somiya H (1979) ‘Yellow lens’ eyes and luminous organs ofEchiostoma barbatum (Stomiatoidei, Melanostomiatidae). Jpn J Ichthyol 25:269–272

    Google Scholar 

  • Somiya H (1982) ‘Yellow lens’ eyes of a stomiatoid deep-sea fish,Malacosteus niger. Proc R Soc Lond B 215:481–489

    Google Scholar 

  • Taylor AH, Kerr GP (1941) The distribution of energy in the visible spectrum of daylight. J Opt Soc Am 31:3–8

    Google Scholar 

  • Vetter W, Englert G, Rigassi N, Schweiter V (1971) Spectroscopic methods. In: Isler O (ed) Carotenoids. Birkhäuser, Basel Stuttgart, p 189

    Google Scholar 

  • Villermet GM, Weale RA (1972) Age, the crystallin lens of the rudd and visual pigments. Nature 238:345–346

    Google Scholar 

  • Walls GL, Judd HD (1933) The intra-ocular colour-filters of vertebrates. Br J Ophthalmol 17:641–675

    Google Scholar 

  • Zigman S (1971) Eye lens color: Formation and function. Science 171:807–809

    Google Scholar 

  • Zigman S (1975) Coloration in human lens protein. Exp Eye Res 20:489–492

    Google Scholar 

  • Zigman S (1983) Effects of near ultraviolet radiation on the lens and retina. Doc Ophthalmol 55:375–391

    Google Scholar 

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McFall-Ngai, M., Crescitelli, F., Childress, J. et al. Patterns of pigmentation in the eye lens of the deep-sea hatchetfish,Argyropelecus affinis Garman. J. Comp. Physiol. 159, 791–800 (1986). https://doi.org/10.1007/BF00603732

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