Summary
To confirm the identity of presumed photoreceptor-like neurones displaced from their normal location in the developing retina we have examined their morphology and extent of occurrence in the Long-Evans hooded rat aged one to six weeks postnatally. Displaced photoreceptor cells (PR) in the inner nuclear layer showed changing nuclear chromatin patterns during retinal development akin to those occurring in PR cells in the outer nuclear layer. PR cell cytoplasmic specializations included outer segments in various stages of formation and presynaptic terminal features including synaptic ribbons and vesicles. Processes abutting on PR cell terminals did not have postsynaptic specializations. Displaced PR cells may have arisen from PR progenitors which failed to retain a foothold at the retina's ventricular surface. The incidence of displaced PR cells determined from quantification of their planimetric densities decreased from 18% of the INL cell population day 9 postnatally to less than 2% at day 15. A few such cells remained even at 36 days. Their fate appeared to be migration to the ONL and, or, in situ degeneration. Counts of necrotic cells carried out at ages preceding, during, and following the period during which ectopic PR cells were most numerous indicated that the decline in numbers of displaced PR cells coincided temporally with the period during which cell degeneration in the INL was most promilent. Degeneration of cells in the INL, including ectopic PR cells, was sufficient to account for a considerable proportion of the retinal thinning that occurred during development. Results suggest that future studies of retinal development in genetically or experimentally manipulated animals should consider abnormalities in cell migration and death.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abercrombie M (1946) Estimation of nuclear population from microtome sections. Anat Rec 94:239–247
Planks JC, Bok D (1977) An autoradiographic analysis of postnatal cell proliferation in the normal and degenerative mouse retina. J Comp Neurol 174:317–327
Braekevelt CR, Hollenberg MJ (1970) The development of the retina of the albino rat. Am J Anat 127:281–302
Cammermeyer J (1978) Is the solitary dark neuron a manifestation of postmortem trauma to the brain inadequately fixed by perfusion?. Histochemistry 56:97–115
Chan-Palay V (1972) Arrested granule cells and their synapses with mossy fibers in the molecular layer of the cerebellar cortex. Z Anat Entwicklungsgesch 139:11–20
Fisher LJ (1976) Synaptic arrays of the inner plexiform layer in the developing retina of Xenopus. Dev Biol 50:402–412
Fry KR, Hudy SM, Spira AW, Hannah RS (1981) Cell death in the developing retina. Anat Rec 199: 87A
Glücksmann A (1940) Development and differentiation of the tadpole eye. Br J Ophthalmol 24:153–178
Hild W, Callas G (1967) The behaviour of retinal tissue in vitro, light and electron microscopic observations. Zeit Zellforsch 80:1–21
Hinds JW, Hinds PL (1974) Early ganglion cell differentiation in the mouse retina: an electron microscopic analysis utilizing serial sections. Dev Biol 37:381–416
Hinds JW, Hinds PL (1978) Early development of amacrine cells in the mouse retina: an electron microscopic serial section analysis. J Comp Neurol 179:277–300
Hinds JW, Hinds PL (1979) Differentiation of photoreceptors and horizontal cells in the embryonic mouse retina: an electron microscopic, serial section analysis. J Comp Neurol 187:495–512
Hughes A (1961) Cell degeneration in the larval ventral horn of Xenopus laevis (Daudin). J Embryol Exp Morph 9:269–284
Johns PR, Rusoff AC, Dubin MW (1979) Postnatal neurogenesis in the kitten retina. J Comp Neurol 187:545–555
Landis S (1973) Granule cell heterotopia in normal and nervous mutant mice of the BALB/c strain. Brain Res 61:175–189
La Vail MM, Hild W (1971) Histotypic organization of the rat retina in vitro. Zeit Zellforsch 114:557–579
Mann I (1928) The process of differentiation of the retinal layers in vertebrates. Br J Ophthalmol 12:449–478
McLoon LK, Lund RD, McLoon SC (1982) Transplantation of reaggregates of embryonic neural retinae to neonatal rat brain: differentiation and formation of connections. J Comp Neurol 205:179–189
McLoon SK, McLoon SC, Lund RD (1981) Cultured embryonic retinae transplanted to rat brain: differentiation and formation of projections to host superior colliculus. Brain Res 226:15–31
Raedler A, Sievers J (1975) The development of the visual system of the albino rat. Adv Anat Embryol Cell Biol 50:3–88
Rakic P, Sidman RL (1973) Organization of cerebellar cortex secondary to deficit of granule cells in weaver mutant mice. J Comp Neurol 152:133–162
Sanyal S, Bal AK (1973) Comparative light and electron microscopic study of retinal histogenesis in normal and rd mutant mice. Z Anat Entwickl-Gesch 142:219–238
Sidman RL (1961) Histogenesis of mouse retina studied with thymidine H3. In: GK Smelser (ed) The structure of the eye. Academic Press, New York, pp 487–506
Sjöstrand FS (1958) Ultrastructure of retinal rod synapses of the guinea pig eye as revealed by three-dimensional reconstructions from serial sections. J Ultrastruc Res 2:122–170
Spaček J, Pařizek J, Lieberman AR (1973) Golgi cells, granule cells and synaptic glomeruli in the molecular layer of the rabbit cerebellar cortex. J Neurocytol 2:407–428
Spira AW, Patten M, Hannah R (1981) Displaced photoreceptor cells in the developing rat retina. Soc Neurosci Abst 7:465
Tucker GS (1978) Light microscopic analysis of the kitten retina: postnatal development in the area centralis. J Comp Neurol 180:489–500
Vogel M (1978) Postnatal development of the cat's retina: a concept of maturation obtained by qualitative and quantitative examinations. Adv Anat Embryol Cell Biol 54:1–66
Vogel M, Möller K (1980) Cellular decay in the rat retina during normal post-natal development. A preliminary quantitative analysis of the basic endogenous rhythm. Graefes Arch Clin Exp Opthalmol 212:243–260
Weidman TA, Kuwabara T (1968) Postnatal development of the rat retina. An electron microscopic study. Arch Opththalmol 79:470–484
Wimer C (1977) A method for estimating diameter to correct for split nuclei in neuronal counts. Brain Res 133:376–381
Author information
Authors and Affiliations
Additional information
Supported by the Medical Research Council of Canada, Alberta Mental Health Foundation and Alberta Heritage Foundation Medical Research
Rights and permissions
About this article
Cite this article
Spira, A., Hudy, S. & Hannah, R. Ectopic photoreceptor cells and cell death in the developing rat retina. Anat Embryol 169, 293–301 (1984). https://doi.org/10.1007/BF00315634
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00315634