Abstract
By rearing fish in various monochromatic illuminations we investigated (1) the potential for compensation of refractive error due to chromatic aberration, (2) the contributions of the chromatic channels to emmetropization, and (3) the role of color cues in the control of eye growth. Cichlid fish (Aequidens pulcher) were reared for 6 months (12 h light/12 h dark) in monochromatic lights (623.5, 534.1, 485.0 nm; spectral purity 5–10 nm). Light levels were isoirradiant at 1.1·1012 quanta/s/cm2. Two control groups were reared in white light with down-welling illuminances of 0.2 and 33 lx. Nasotemporal diameters (NTDs) of the eyes were measured in relation to lens size. Due to the oblique axis of highest acuity vision in cichlids, NTD is considered to be a more important dimension than axial length. Variances in NTD were equally small in all rearing groups. NTDs were enlarged with increasing wavelengths of the rearing lights with highly significant values over controls in the red-light group. The wavelength-dependent size of the eyes matched the changes in focal length due to longitudinal chromatic aberration. Complete recovery from eye enlargement was observed after fish reared in red light were exposed to a white light regime for 5 weeks. Small variances in NTD in all groups indicated stringent control of eye growth in the absence of color cues. The reversibility of the increase in NTD in fish reared in red light suggests that the eyes were emmetropized by visually guided mechanisms. Eye size in fish reared in white light was intermediate between the values expected if only blue-sensitive single or the red- and green-sensitive double cones contributed to the control of eye growth. This suggests that all chromatic channels participate in emmetropizing the fish eye.
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References
Curtin BJ (1985) The myopias: basic science and clinical management. Harper and Row, New York
Fernald RD (1981) Chromatic organization of a cichlid fish retina. Vision Res 21: 1749–1753
Fernald RD (1988) Aquatic adaptations in fish eyes. In: Atema J, Fay RR, Popper AN, Tavolga WN (eds) Sensory biology of aquatic animals. Springer, Berlin Heidelberg New York, pp. 435–466
Fernald RD, Wright S (1985a) Growth of the visual system of the African cichlid fish, H. burtoni: optics. Vision Res 25: 155–161
Fernald RD, Wright S (1985b) Growth of the visual system of the African cichlid fish, H. burtoni: accommodation. Vision Res 25: 163–170
Hodos W, Kuenzel WJ (1984) Retinal-image degradation produces ocular enlargement in chicks. Invest Ophthalmol Vis Sci 25: 652–659
Holden AL, Hodos W, Hayes BP, Fitzke FW (1988) Myopia: induced, normal and clinical. Eye 2: 242–256
Irving EL, Sivak JG, Callender MG (1992) Refractive plasticity of the developing chick eye. Ophthalmol Physiol Opt 12: 448–456
Kröger RHH, Campbell MCW (1993) Spherical and chromatic aberration in the eye lens of a fish. Invest Ophthalmol Vis Sci 34: 773
Kröger RHH, Campbell MCW (1996) Dispersion and longitudinal chromatic aberration of the crystalline lens of the African cichlid fish Haplochromis burtoni. J Opt Soc Am A (in press)
Kröger RHH, Fernald RD (1994) Regulation of eye growth in the African cichlid fish Haplochromis burtoni. Vision Res 34: 1807–1814
Levine JS, MacNichol EF (1979) Visual pigments in teleost fishes: effects of habitat, microhabitat and behaviour on visual system evolution. Sens Process 3: 95–131
Mandelman T, Sivak JG (1983) Longitudinal chromatic aberration of the vertebrate eye. Vision Res 23: 1555–1559
Matthiessen L (1886) Ueber den physikalisch-optischen Bau des Auges der Cetaceen und der Fische. Pflügers Arch 38: 521–528
Miles FA, Wallman J (1990) Local ocular compensation for imposed local refractive error. Vision Res 30: 339–349
Otten E (1981) Vision during growth of a generalized Haplochromis species: H. elegans Trewavas 1993 (Pisces, Cichlidae). Neth J Zool 31: 650–700
Rohrer B, Schaeffel F, Zrenner E (1992) Longitudinal chromatic aberration and emmetropization: results from the chicken eye. J Physiol (Lond) 449: 363–376
Schaeffel F, Howland HC (1988) Mathematical model of emmetropization in the chicken. J Opt Soc Am A 5: 2080–2086
Schaeffel F, Howland HC (1991) Properties of the feedback loops controlling eye growth and refractive state in the chicken. Vision Res 31: 717–734
Schaeffel F, Howland HC (1995) Guest editorial (special issue on myopia). Vision Res 35: 1135–1139
Schaeffel F, Glasser A, Howland HC (1988) Accommodation, refractive error and eye growth in chickens. Vision Res 28: 639–657
Schaeffel F, Troilo D, Wallman J, Howland HC (1990) Developing eyes that lack accommodation grow to compensate for imposed defocus. Vis Neurosci 4: 177–183
Scholes JH (1975) Colour receptors and the synaptic connexions in the retina of a cyprinid fish. Phil Trans R Soc Lond B 270: 61–118
Sivak JG, Bobier WR (1978) Chromatic aberration of the fish eye and its effect on refractive state. Vision Res 18: 453–455
Sroczyński S (1976) Die chromatische Aberration der Augenlinse der Regenbogenforelle (Salmo gairdneri, Rich.). Zool Jahrb (Physiol) 80: 432–450
Sroczyński S (1978) Die chromatische Aberration der Augenlinse der Bachforelle (Salmo trutta fario L.). Zool Jahrb (Physiol) 82: 113–133
Sroczyński S (1979) Das optische System des Auges des Flussbarsches (Perca fluviatilis L.). Zool Jahrb (Physiol) 83: 224–252
Stavenga DG, Smits RP, Hoenders BJ (1993) Simple exponential functions describing the absorbance bands of visual pigment spectra. Vision Res 33: 1011–1017
Troilo D (1992) Neonatal eye growth and emmetropisation — a literature review. Eye 6: 154–160
Troilo D, Gottlieb MD, Wallman J (1987) Visual deprivation causes myopia in chicks with optic nerve section. Curr Eye Res 6: 993–999
Wagner H-J (1972) Vergleichende Untersuchungen über das Muster der Sehzellen und Horizontalen in der Teleostier-Retina (Pisces). Z Morphol Tiere 72: 77–130
Wallman J (1993) Retinal control of eye growth and refraction. Prog Retinal Res 12: 133–153
Wallman J, Turkel J, Trachtman J (1978) Extreme myopia produced by modest change in early visual experience. Science 201: 1249–1251
Wallman J, Gottlieb MD, Rajaram V, Fugate-Wentzek LA (1987) Local retinal regions control local eye growth and myopia. Science 237: 73–76
Wiesel TN, Raviola E (1977) Myopia and eye enlargement after neonatal lid fusion in monkeys. Nature 266: 66–68
Wiesel TN, Raviola E (1979) Increase in axial length of the macaque monkey eye after corneal opacification. Invest Ophthalmol Vis Sci 18: 1232–1236
Wildsoet C, Howland HC (1991) Chromatic aberration and accommodation: their role in emmetropization in the chick. Invest Ophthalmol Vis Sci 32: 1203
Wildsoet C, Wallman J (1995) Choriodal and scleral mechanisms of compensation for spectacle lenses in chicks. Vision Res 35: 1175–1194
Yinon U (1984) Myopia induction in animals following alteration of the visual input during development: a review. Curr Eye Res 3: 677–690
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Kröger, R.H.H., Wagner, H.J. The eye of the blue acara (Aequidens pulcher, Cichlidae) grows to compensate for defocus due to chromatic aberration. J Comp Physiol A 179, 837–842 (1996). https://doi.org/10.1007/BF00207362
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DOI: https://doi.org/10.1007/BF00207362