The organization of perpendicular fibre pathways in the insect optic lobe.

High resolution serial photomicrography has been used to plot the axonal projection patterns between retina, lamina and medulla in the optic lobes of various insects with differing ommatidial receptor arrangements. Observations are reported on the cabbage white and skipper butterflies, the bee, locust, fly, backswimmer and waterbug. The patterns of these fibre pathways have previously eluded non-rigorous analyses primarily because of their physical dimensions but are revealed in this study to have striking precision and uniformity between species when examined at the level of individually identifiable cells. Axon bundles of the tracts between retina and lamina or lamina and medulla project between a single ommatidium and its corresponding lamina cartridge or between corresponding lamina and medulla cartridges. Lateral interweaving of axons between adjacent bundles is absent. The bundles preserve the retinotopic order within their total array, so transferring the pattern of retinulae directly upon the lamina and thence after horizontal inversion in the chiasma upon the medulla. Within the lamina neuropile on the other hand the trajectories of the individual terminals from a bundle have patterns which are species-specific, sometimes involving lateral divergences. In species with open-rhabdomere ommatidia the terminals distribute to a group of lamina cartidges with a pattern which resembles the receptor pattern in the overlying ommatidium. In species with fused-rhabdome ommatidia the terminals of a single retinula behave less interestingly and all enter the same cartridge, within which, again, each occupies a position related to its cell body position within the retinula. Long visual fibres in both eye types penetrate the lamina and terminate in the particular medulla cartridge that connects with the lamina cartridge underlying their ommatidium. The perpendicular fibre pathways therefore project the visual field exactly upon the medulla in all species while the lack of interweaving between adjacent fibre bundles precludes their involvement in lateral interactions between pathways with differing visual axes. Uniformity of these projection patterns between cell layers and species differences in retinular terminal locations in the lamina can be correlated with different modes of axon growth between and within neuropile layers during optic lobe neurogenesis. Further discussion surrounds the question of which particular receptors give rise to which type of axon, for which no clear generalization has yet emerged.

[1]  N. Strausfeld,et al.  Synaptic connections of intrinsic cells and basket arborizations in the external plexiform layer of the fly's eye. , 1973, Brain research.

[2]  O. Trujillo-Cenóz Some aspects of the structural organization of the intermediate retina of dipterans. , 1965, Journal of ultrastructure research.

[3]  O. Trujillo-Cenóz,et al.  Compound eye of dipterans: anatomical basis for integration--an electron microscope study. , 1966, Journal of ultrastructure research.

[4]  Russell J. Barrnett,et al.  Cytochemistry and electron microscopy. The preservation of cellular ultrastructure and enzymatic activity by aldehyde fixation. , 1963 .

[5]  George Adrian Horridge,et al.  The superposition eye of skipper butterflies , 1972, Proceedings of the Royal Society of London. Series B. Biological Sciences.

[6]  F. Gribakin The distribution of the long wave photoreceptors in the compound eye of the honey bee as revealed by selective osmic staining. , 1972, Vision research.

[7]  G. Horridge,et al.  Structure and function in the nervous systems of invertebrates , 1965 .

[8]  S. Swihart Colour vision and the physiology of the superposition eye of a butterfly (Hesperiidae). , 1969, Journal of insect physiology.

[9]  S. R. Shaw,et al.  Retinal resistance barriers and electrical lateral inhibition , 1975, Nature.

[10]  I A Meinertzhagen,et al.  The accuracy of the patterns of connexions of the first- and second-order neurons of the visual system of Calliphora , 1970, Proceedings of the Royal Society of London. Series B. Biological Sciences.

[11]  G. Horridge Affinity of Neurones in Regeneration , 1968, Nature.

[12]  O. Trujillo-Cenóz,et al.  Some aspects of the structural organization of the medulla in muscoid flies. , 1969, Journal of ultrastructure research.

[13]  F. G. Varela,et al.  Fine structure of the visual system of the honeybee (Apis mellifera). I. The retina. , 1969, Journal of ultrastructure research.

[14]  E. Eguchi Rhabdom structure and receptor potentials in single crayfish retinular cells. , 1965, Journal of cellular physiology.

[15]  O. J. Grundler Elektronenmikroskopische Untersuchungen am Auge der Honig biene (Apis mellifica). I. Untersuchungen zur Morphologie und Anordnung der neun Retinulazellen in Ommatidien versc hiedenerAugenbereiche und zur Perzeption linear polarisier ten Lichtes , 1974 .

[16]  V. B. Meyer-Rochow Axonal wiring and polarisation sensitivity in eye of the rock lobster , 1975, Nature.

[17]  Bertil Hanström Vergleichende Anatomie des Nervensystems der wirbellosen Tiere: unter Berücksichtigung seiner Funktion , 1929, Nature.

[18]  N. J. Strausfeld,et al.  Some Interrelationships between the First and Second Synaptic Regions of the Fly’s (Musca domestica L.) Visual System , 1972 .

[19]  I. Meinertzhagen The development of neuronal connection patterns in the visual systems of insects. , 1975, Ciba Foundation symposium.

[20]  P. Herrling Measurements on the Arrangement of Ommatidial Structures in the Retina of Cataglyphis bicolor (Formicidae, Hymenoptera) , 1972 .

[21]  R. Wehner,et al.  Fine structure of light‐ and dark‐adapted eyes of desert ants, Cataglyphis bicolor (Formicidae, Hymenoptera) , 1973, Journal of morphology.

[22]  C. Levinthal,et al.  Structure and development of neuronal connections in isogenic organisms: variations and similarities in the optic system of Daphnia magna. , 1973, Proceedings of the National Academy of Sciences of the United States of America.

[23]  D W Arnett,et al.  Spatial and temporal integration properties of units in first optic ganglion of dipterans. , 1972, Journal of neurophysiology.

[24]  N. Strausfeld,et al.  The optic lobes of Lepidoptera. , 1970, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[25]  N. Strausfeld,et al.  The L4 monopolar neurone: a substrate for lateral interaction in the visual system of the fly Musca domestica (L.). , 1973, Brain research.

[26]  N. Strausfeld The optic lobes of Diptera. , 1970, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[27]  O. Trujillo-Cenóz,et al.  The Structural Organization of the Compound Eye in Insects , 1972 .

[28]  M. Karnovsky,et al.  A formaldehyde-glutaraldehyde fixative of high osmolality for use in electron-microscopy , 1965 .

[29]  J. Brammer The ultrastructure of the compound eye of a mosquito Aedes aegypti L , 1970 .

[30]  Gary D. Bernard,et al.  THE VISUAL SYSTEM OF INSECTS , 1974 .

[31]  G. Palade A STUDY OF FIXATION FOR ELECTRON MICROSCOPY , 1952, The Journal of experimental medicine.

[32]  Erroneous projection of retinula axons beneath a dislocation in the retinal equator of Calliphora. , 1972, Brain research.

[33]  P. Burton,et al.  Electron microscopic studies of the compound eye of the toadbug, Gelastocoris oculatus , 1969 .

[34]  O. Trujillo-Cenóz,et al.  The fine structure of the central cells in the ommatidia of dipterans. , 1967, Journal of ultrastructure research.

[35]  O. Trujillo-Cenóz,et al.  The development of the retina-lamina complex in muscoid flies. , 1973, Journal of ultrastructure research.

[36]  G. Horridge,et al.  The retina of Ephestia (Lepidoptera) , 1971, Proceedings of the Royal Society of London. Series B. Biological Sciences.