In the fetal monkey the projections from the two eyes are initially completely intermingled within the dorsal lateral geniculate nucleus (DLGN) before separating into eye-specific layers (Rakic, 1976). To assess the cellular basis of this developmental process, we examined the morphological properties of individual retinogeniculate axons in prenatal monkeys of known gestational ages. The period studied spanned the time from when binocular overlap has been reported to be maximum, circa embryonic (E) day 77 through E112, when the segregation process is already largely completed in the caudal portion of the nucleus. Retinogeniculate fibers were labeled by making small deposits of DiI crystals into the fixed optic tract. After adequate time was allowed for diffusion of the tracer, fibers were visualized by confocal microscopy, and morphometric measures were made from photomontages. This revealed that retinogeniculate fibers in the embryonic monkey undergo continuous growth and elaboration during binocular overlap and subsequent segregation. Importantly, very few side-branches were found along the preterminal axon throughout the developmental period studied. Thus, restructuring of retinogeniculate fibers does not underlie the formation of eye-restricted projections in the primate. Rather, the results support the hypothesis that binocular segregation in the embryonic monkey is caused by the loss of retinal fibers that initially innervate inappropriate territories (Rakic, 1986). Key words: retinogeniculate projections; primate; prenatal development; terminal arborizations; binocular segregation; dorsal lateral geniculateThe overlap and subsequent segregation of retinogeniculate projections was first demonstrated by Rakic (1976) by means of intraocular injections of tritiated amino acids in fetal monkeys. Since then, the intermingling and later sorting out of binocular inputs has been shown in many species, suggesting that this is a common feature of the mammalian visual system (Chalupa and Dreher, 1991). This developmental process could result from different cellular mechanisms, including the loss of retinal fibers, a retraction of retinogeniculate terminal arbors, and the elimination of axonal side-branches.In the monkey, approximately 3 million ganglion cell axons are generated during fetal development, whereas only approximately 1 million survive to maturity (Rakic and Riley, 1983a). Moreover, the time course of fiber loss corresponds to the period when eye-specific projection patterns become established. This temporal correspondence suggests that the loss of retinal fibers that initially innervate inappropriate eye-specific territories within the geniculate anlage could be responsible for binocular segregation. This hypothesis is f urther supported by the finding that removal of one eye during the binocular overlap period results in a significant increase in the number of fibers in the remaining optic nerve and an expanded retinogeniculate projection from the remaining eye (Rakic and Riley, 1983b;Rakic, 1986).There...
At maturity, ON and OFF alpha ganglion cells in the cat retina are arrayed in regular mosaics, with adjacent cells commonly forming ON-OFF pairs. In the present study, we investigated the role of activity-mediated ganglion cell death in the formation of such cellular patterns. Because direct measures of ganglion cell mosaics are problematic in the developing retina, we examined the distributions of ON and OFF alpha cells in the postnatal cat retina by assessing the degree to which cells in closest proximity were of opposite sign (i.e., ON-OFF pairs). Computer simulations demonstrated that superimposition of two regular distributions results in a high incidence (approximately 90%) of opposite sign pairs. This is also the case for ON and OFF alpha cells in the mature retina, reflecting the high degree of regularity exhibited by this cell class. In contrast, during the first postnatal month, alpha cells displayed a much lower incidence of opposite sign pairs (approximately 60%), comparable to the superimposition of two simulated random distributions. We also show that there is a 20% loss of alpha cells in the central retina during postnatal development and that this magnitude of loss is sufficient to form regular distributions of ON and OFF cells. To assess the influence of sodium voltage-gated activity on this developmental process, intraocular injections of tetrodotoxin (TTX) were made during the postnatal period of alpha cell loss. When the TTX-treated animals reached maturity, there was a dose-related decrease in the incidence of opposite sign pairs, without any appreciable change in cell density. Moreover, the regularity index of ON and OFF cells was significantly lower than normal in the TTX-treated retinas. These findings demonstrate that a spatially selective pattern of ganglion cell loss contributes to the formation of regular ON and OFF ganglion cell distributions and that such cell loss is regulated by retinal activity.
To assess the degree of order exhibited during development by crossed and uncrossed retinocollicular pathways, focal deposits of 1,1'-dioctodecyl-3,3,3'3'-tetramethylinodocarbocyanine perchlorate (DiI) were made into the temporal or nasal retina of prenatal and postnatal ferrets. This procedure revealed that the first retinal fibers (from the ipsilateral temporal retina) grow into the superior colliculus at embryonic (E) day 30. Both crossed and uncrossed fibers innervate the colliculus by E34. At this age, terminal arbors were lacking, and there was no evidence of extensive axonal branching. Retinocollicular arbors first appeared at E38, with both the crossed and uncrossed projections forming well-defined terminal zones that appeared to be localized to topographically appropriate regions. At E38, the ipsilateral terminal zone was significantly larger but notably less dense than the contralateral zone. At this and later ages (postnatal day [P] 0 and P7), a few crossed and uncrossed fibers extended beyond the terminal zone. Four days later, at P0, the terminal zone of the uncrossed projection was reduced in size in comparison with that of earlier ages, whereas the crossed projection became substantially larger. By P7, the few misprojecting fibers seen in younger ferrets had been virtually eliminated. When focal retinal deposits of tracer were made into the nasal retina of E36 and E40 ferrets, crossed fibers were found to innervate the caudal segment of the superior colliculus. These crossed nasal cells appear to project to the topographically appropriate region of the superior colliculus (caudal segment) but on the wrong side of the brain. Collectively, the present findings indicate that throughout development the ferret retinocollicular pathway is characterized by a remarkable degree of topographic precision as evident by the paucity of axonal branches and the low number of grossly misprojecting axons.
Polyclonal (7493 and 7317) and monoclonal (mAb3) antibodies, generated to the α subunit of the voltage-gated sodium channel (αNaCh), were employed to assess the cell types containing αNaCh-like immunoreactivity in the mature cat and monkey retina. Immunoblot analyses of retinal proteins in the cat revealed that the polyclonal and monoclonal antibodies we employed labeled a band in the 260–kDa region which corresponds to the molecular mass of the α subunit of the NaCh. In both the cat and monkey, these antibodies immunolabeled several distinct types of retinal cells. With the polyclonal antibodies immunoreactivity was observed in ganglion cells and their intraretinal axons, in horizontal cells, and unexpectedly, in cones. In addition, in both species, a limited number of heavily labeled profiles, presumed to be bipolar cells, were seen in the inner nuclear layer. In cat and monkey the monoclonal antibody labeled axons in the fiber layer, ganglion cell somata, and a continuous band of immunoreactive cell bodies (presumed bipolar cells) situated in the outer half of the inner nuclear layer. By immunolabeling isolated cells dissociated from the cat retina, it was possible to demonstrate unequivocally that a population of bipolar cells was labeled by the monoclonal and the polyclonal antibodies we employed. The differences in the labeling observed with the monoclonal antibody as compared to the polyclonal antibodies were interpreted as reflecting the presence of different α-subunit subtypes in the mammalian retina. Collectively, our findings suggest that αNaCh-like proteins are expressed by a more diverse population of retinal cells than expected on the basis of previous physiological and immunohistochemical studies.
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