In Vitro Protein Synthesis in the Goldfish Retinotectal Pathway During Regeneration: Evidence for Specific Axonal Proteins of Retinal Origin in the Optic Nerve

Four proteins with molecular weights of 58,000 can be separated as a linear array by two-dimensional gel electrophoresis. They are highly concentrated in the goldfish optic nerve and are designated as ON1, ON2, ON3, and ON4. Proteins ON1 and ON2 are undetectable in the optic nerve after disconnection and their concentration is gradually restored during regeneration. In vitro incubations of retinas, optic nerves, or tecta in the presence of [35S]methionine indicate that proteins ON1 and ON2 are of retinal origin. The labeling rate of these proteins in the retina increases fourfold after optic nerve crush whereas the overall labeling rate in the retina remains largely constant. Their synthesis cannot be detected in tissues devoid of retinal ganglion cells. This is consistent with the view that ON1 and ON2 are synthesized by retinal ganglion cells and are consequently of neuronal origin in the optic nerve. In contrast, similar experiments indicate that ON3 and ON4 are of nonneuronal origin. They are synthesized in the optic nerve in the absence of retinal ganglion cells.     

Na,K-ATPase alpha3 subunit in the goldfish retina during optic nerve regeneration

The goldfish optic nerve can regenerate after injury. To understand the molecular mechanism of optic nerve regrowth, we identified genes whose expression is specifically up-regulated during the early stage of optic nerve regeneration. A cDNA library constructed from goldfish retina 5 days after transection was screened by differential hybridization with cDNA probes derived from axotomized or normal retina. Of six cDNA clones isolated, one clone was identified as the Na,K-ATPase catalytic subunit alpha3 isoform by high- sequence homology. In northern hybridization, the expression level of the mRNA was significantly increased at 2 days and peaked at 5-10 days, and then gradually decreased and returned to control level by 45 days after optic nerve transection. Both in situ hybridization and immunohistochemical staining have revealed the location of this transient retinal change after optic nerve transection. The increased expression was observed only in the ganglion cell layer and optic nerve fiber layer at 5-20 days after optic nerve transection. In an explant culture system, neurite outgrowth from the retina 7 days after optic nerve transection was spontaneously promoted. A low concentration of ouabain (50-100 nm ) completely blocked the spontaneous neurite outgrowth from the lesioned retina. Together, these data indicate that up-regulation of the Na,K-ATPase alpha3 subunit is involved in the regrowth of ganglion cell axons after axotomy.     

Molecular cloning of gefiltin (ON1): serial expression of two new neurofilament mRNAs during optic nerve regeneration.

The goldfish visual pathway displays a remarkable capacity for continued development and plasticity. The intermediate filament proteins of this pathway do not match the intermediate filament protein composition of adult higher vertebrate neurons, which lack the capacity for growth and development. Using a goldfish retina lambda gt10 library we isolated cDNA clones representing the predominant goldfish optic nerve neurofilament protein, ON1. The mRNA for this protein is abundant in retinal ganglion cells, and its level increases slowly during optic nerve regeneration. The rate of ON1 mRNA accumulation after optic nerve crush was compared with that of plasticin, a previously described novel type III neurofilament from goldfish retinal ganglion cells. Plasticin mRNA is normally expressed at low steady state levels, but accumulates dramatically and rapidly, preceding gefiltin mRNA, in response to optic nerve crush. The predicted amino acid sequence for ON1 indicates that it is a novel intermediate filament protein. We have named it gefiltin, for goldfish eye intermediate filament protein. The serial expression of plasticin and gefiltin is discussed with respect to the diversity of neurofilament proteins during neurogenesis.     

Distribution of neurotrophin-3 during the ontogeny and regeneration of the lizard (Gallotia galloti) visual system

We have previously described the spontaneous regeneration of retinal ganglion cell axons after optic nerve (ON) transection in the adult Gallotia galloti. As neurotrophin-3 (NT-3) is involved in neuronal differentiation, survival and synaptic plasticity, we performed a comparative immunohistochemical study of NT-3 during the ontogeny and regeneration (after 0.5, 1, 3, 6, 9, and 12 months postlesion) of the lizard visual system to reveal its distribution and changes during these events. For characterization of NT-3(+) cells, we performed double labelings using the neuronal markers HuC-D, Pax6 and parvalbumin (Parv), the microglial marker tomato lectin or Lycopersicon esculentum agglutinin (LEA), and the astroglial markers vimentin (Vim) and glial fibrillary acidic protein (GFAP). Subpopulations of retinal and tectal neurons were NT-3(+) from early embryonic stages to adulthood. Nerve fibers within the retinal nerve fiber layer, both plexiform layers and the retinorecipient layers in the optic tectum (OT) were also stained. In addition, NT-3(+)/GFAP(+) and NT-3(+)/Vim(+) astrocytes were detected in the ON, chiasm and optic tract in postnatal and adult lizards. At 1 month postlesion, abundant NT-3(+)/GFAP(+) astrocytes and NT-3(-)/LEA(+) microglia/macrophages were stained in the lesioned ON, whereas NT-3 became downregulated in the experimental retina and OT. Interestingly, at 9 and 12 months postlesion, the staining in the experimental retina resembled that in control animals, whereas bundles of putative regrown fibers showed a disorganized staining pattern in the OT. Altogether, we demonstrate that NT-3 is widely distributed in the lizard visual system and its changes after ON transection might be permissive for the successful axonal regrowth.     

Up-regulation of protein kinase C in regenerating optic nerve fibers of goldfish: Immunohistochemistry and kinase activity assay

Protein kinase C (PKC) activation has been associated with synaptic plasticity in many projections, and manipulating PKC in the retinotectal projection strongly affects the activity-driven sharpening of the retinotopic map. This study examined levels of PKC in the regenerating retinotectal projection via immunostaining and assay of activity. A polyclonal antibody to the conserved C2 (Ca²⁺ binding) domain of classical PKC isozymes (anti-panPKC) recognized a single band at 79–80 kD on Western blots of goldfish brain. It stained one class of retinal bipolar cells and the ganglion cells in normal retina, as shown previously. Strong staining was not present in the optic fiber layer of retina or in optic nerve, optic tract, or terminal zone in tectum, with the exception of a single fascicle of optic nerve fibers that by their location and by L1 (E587) staining were identified as those arising from newly added ganglion cells at the retinal margin. Normal tectal sections showed dark staining of a subclass of type XIV neuron with somas at the top of the periventricular layer and an apical dendrite ascending to stratum opticum. In regenerating retina, swollen ganglion cells stained darkly and stained axons were seen in the optic fiber layer. In regenerating optic nerve (2–11 weeks postcrush), all fascicles of optic fibers stained darkly for both PKC and L1(E587). At 5 weeks postcrush, PKC staining could also be seen in the medial and lateral optic tracts and stratum opticum at the front half of the tectum and very lightly over the terminal zones. PKC activity was measured in homogenized tissues dissected from a series of fish with unilateral nerve crush from 1 to 5 weeks previously. Activity levels stimulated by phorbols and Ca²⁺ were measured by phosphorylation of a specific peptide and referred to levels measured in the opposite control side. Regeneration did not increase overall PKC activity in retina or tectum, but in optic nerve there was an 80% rise after the first week. The increased activity verifies that the increased staining in nerve represented an up-regulation of functional PKC during nerve regeneration. © 1998 John Wiley & Sons, Inc. J Neurobiol 36: 315–324, 1998     

Optic nerve regeneration after intravitreal peripheral nerve implants: trajectories of axons regrowing through the optic chiasm into the optic tracts

We have studied axon regeneration through the optic chiasm of adult rats 30 days after prechiasmatic intracranial optic nerve crush and serial intravitreal sciatic nerve grafting on day 0 and 14 post-lesion. The experiments comprised three groups of treated rats and three groups of controls. All treated animals received intravitreal grafts either into the left eye after both left sided (unilateral) and bilateral optic nerve transection, or into both eyes after bilateral optic nerve transection. Control eyes were all sham grafted on day 0 and 14 post-lesion, and the optic nerves either unlesioned, or crushed unilaterally or bilaterally. No regeneration through the chiasm was seen in any of the lesioned control optic nerves. In all experimental groups, large numbers of axons regenerated across the optic nerve lesions ipsilateral to the grafted eyes, traversed the short distal segment of the optic nerve and invaded the chiasm without deflection. Regeneration was correlated with the absence of the mesodermal components in the scar. In all cases, axon regrowth through the chiasm appeared to establish a major crossed and a minor uncrossed projection into both optic tracts, with some aberrant growth into the contralateral optic nerve. Axons preferentially regenerated within the degenerating trajectories from their own eye, through fragmented myelin and axonal debris, and reactive astrocytes, oligodendrocytes, microglia and macrophages. In bilaterally lesioned animals, no regeneration was detected in the optic nerve of the unimplanted eye. Although astrocytes became reactive and their processes proliferated, the architecture of their intrafascicular processes was little perturbed after optic nerve transection within either the distal optic nerve segment or the chiasm. The re-establishment of a comparatively normal pattern of passage through the chiasm by regenerating axons in the adult might therefore be organised by this relatively immutable scaffold of astrocyte processes. Binocular interactions between regenerating axons from both nerves (after bilateral optic nerve transection and intravitreal grafting), and between regenerating axons and the intact transchiasmatic projections from the unlesioned eye (after unilateral optic nerve lesions and after ipsilateral grafting) may not be important in establishing the divergent trajectories, since regenerating axons behave similarly in the presence and absence of an intact projection from the other eye.     

Regeneration of optic nerve fibers of adult mammals

The pathway from the retina to the brain in mammals provides a well-defined model system for investigation of not only surviving axotomy but also axonal regeneration of injured neurons. Here I introduce our recent works on axonal regeneration in the optic nerve (OpN) of adult cats. Fibers of retinal ganglion cells (RGCs) extend beyond the crush site of OpN with injections of a macrophage stimulator (oxidized galectin-1) or a Rho kinase (ROCK) inhibitor (Y-39983 or Y-27632) while axonal extension is blocked with injection of saline. Elongation of crushed optic fibers, however, is slowed after 2 weeks. Transplantation of peripheral nerve makes RGCs regenerate their transected axons into a graft but regenerated fibers extend only a few mm in the brain. Effectiveness of combination of the drugs and treatments has to be verified in future.     

Microglial changes accompanying the promotion of retinal ganglion cell axonal regeneration into peripheral nerve grafts

Intravitreal injection of the microglia inhibitor tuftsin 1-3 leads to an increase in retinal ganglion cell axonal regeneration into peripheral nerve grafts and a decrease in phagocytic cells in the retina. However, the relation of phagocytic cells and particularly microglia towards axonal regeneration remains unclear. Initially, to assess this, tuftsin 1-3's effect on axonal regeneration was reexamined by doing a dose-response study. Optimal doses were found to be 2.5 μg/ml and 250 μg/ml in rats and hamsters respectively. We then studied retinal phagocytic cells in rats. Microglial cells were classified as resting or activated based on their morphology following OX42 immunolabelling. In controls, most microglial cells were in the resting state. Optic nerve cut led to an increase in the total number of microglia and a ten-fold elevation in the proportion of activated cells; changes were more pronounced at the optic nerve stump. Anastomosis of an autologous segment of sciatic nerve to the stump of the freshly cut optic nerve minimized the overall increase in microglia, and combined with 2.5 μg/ml tuftsin 1-3, lead to a marked blunting of activation. Preservation within the retina of a higher proportion of resting over active form of microglia, and not the prevention of microglial proliferation per se, may be a crucial factor in allowing additional retinal ganglion cell axons to regenerate into peripheral nerve grafts.     

Elevated Levels of Retinal Neurofilament mRNA Accompany Optic Nerve Regeneration

RNA isolated from goldfish retinas before and during optic nerve regeneration, when translated in vitro, directed the synthesis of neurofilament proteins that are normally found in high levels in the optic nerve. The major neurofilament proteins of the goldfish optic nerve comprise a group of four isoelectric variants of molecular weight 58,000 (58K) which we have identified previously as ON1-ON4. The levels of ON1 and ON2 within the optic nerve had been shown to decrease shortly after optic nerve crush and then increase to precrush levels during the regeneration process. Employing two-dimensional electrophoretic analysis of in vitro translation products and immunoprecipitations with antibodies specific for the ON proteins and an anti-intermediate filament monoclonal antibody, we show that ON1 and ON2 are encoded by mRNA synthesized in the retinas. The synthesis of ON3 and ON4 by retina RNA was undetected. This confirms data from previous ex vivo experiments that indicated that ON1 and ON2 are of neuronal origin whereas ON3 and ON4 are nonneuronal. ON1 and ON2 synthesis increases dramatically during optic nerve regeneration to levels 10- and 30-fold over precrush levels, respectively. In addition to ON1 and ON2, the synthesis of a previously unidentified 52K protein is observed at relatively high levels 20 and 32 days after optic nerve crush, but is unobserved before regeneration. Thus, optic nerve regeneration can be correlated with specific changes in intermediate filament gene expression within the retina.     

Laminar restriction of retinal macrophagic response to optic nerve axotomy in the rat.

Following optic nerve transection, most of the retinal ganglion cells die. Their debris is promptly cleared by phagocytic cells. It is currently not known to what extent peripherally derived macrophages contribute to this activity. Using antibodies OX42 and ED-1, phagocytic cells were labeled in the retinas of optic nerve lesioned adult rats. To distinguish whether the cells were reactive microglial or macrophagic in origin, blood-borne monocytes were labeled with fluorescent microspheres while in the systemic circulation. Macrophages invaded the retina, but only in the nerve fiber layer, sparing the ganglion cell and other layers. These macrophages engulfed only the axonal debris from dying ganglion cells, not their degenerating cell bodies. These results indicate that although peripherally derived monocytic cells are recruited into the retrogradely degenerating retina, their role in clearing debris is limited to the optic fiber layer.     

A distinct effect of transient and sustained upregulation of cellular factor XIII in the goldfish retina and optic nerve on optic nerve regeneration

Unlike in mammals, fish retinal ganglion cells (RGCs) have a capacity to repair their axons even after optic nerve transection. In our previous study, we isolated a tissue type transglutaminase (TG) from axotomized goldfish retina. The levels of retinal TG (TG(R)) mRNA increased in RGCs 1-6weeks after nerve injury to promote optic nerve regeneration both in vitro and in vivo. In the present study, we screened other types of TG using specific FITC-labeled substrate peptides to elucidate the implications for optic nerve regeneration. This screening showed that the activity of only cellular coagulation factor XIII (cFXIII) was increased in goldfish optic nerves just after nerve injury. We therefore cloned a full-length cDNA clone of FXIII A subunit (FXIII-A) and studied temporal changes of FXIII-A expression in goldfish optic nerve and retina during regeneration. FXIII-A mRNA was initially detected at the crush site of the optic nerve 1h after injury; it was further observed in the optic nerve and achieved sustained long-term expression (1-40days after nerve injury). The cells producing FXIII-A were astrocytes/microglial cells in the optic nerve. By contrast, the expression of FXIII-A mRNA and protein was upregulated in RGCs for a shorter time (3-10days after nerve injury). Overexpression of FXIII-A in RGCs achieved by lipofection induced significant neurite outgrowth from unprimed retina, but not from primed retina with pretreatment of nerve injury. Addition of extracts of optic nerves with injury induced significant neurite outgrowth from primed retina, but not from unprimed retina without pretreatment of nerve injury. The transient increase of cFXIII in RGCs promotes neurite sprouting from injured RGCs, whereas the sustained increase of cFXIII in optic nerves facilitates neurite elongation from regrowing axons.     

Pax genes in development and maturation of the vertebrate visual system: implications for optic nerve regeneration

Pax genes play a pivotal role in development of the vertebrate visual system. Pax6 is the master control gene for eye development: ectopic expression of Pax6 in Xenopus laevis and Drosphila melanogaster leads to the formation of differentiated eyes on the legs or wings. Pax6 is involved in formation of ganglion cells of the retina, as well as cells of the lens, iris and cornea. In addition Pax6 may play a role in axon guidance in the visual system. Pax2 regulates differentiation of the optic disk through which retinal ganglion cell axons exit the eye. Furthermore, Pax2 plays a critical role in development of the optic chiasm and in the guidance of axons along the contralateral or ipsilateral tracts of the optic nerve to visual targets in the brain. During development Pax7 is expressed in neuronal cells of one of the major visual targets in the brain, the optic tectum/superior colliculus. Neurons expressing Pax7 migrate towards the pia and concentrate in the stratum griseum superficiale (SGFS), the target site for retinal axons. Together, expression of Pax2, 6 and 7 may guide axons during formation of functional retinotectal/collicular projections. Highly regulated Pax gene expression is also observed in mature animals. Moreover, evidence suggests that Pax genes are important for regeneration of the visual system. We are currently investigating Pax gene expression in species that display a range of outcomes of optic nerve regeneration. We predict that such information will provide valuable insights for the induction of successful regeneration of the optic nerve and of other regions of the central nervous system in mammals including man.     

Differential expression of calretinin in the developing and regenerating zebrafish visual system

Calretinin is a calcium-binding protein which participates in a variety of functions including calcium buffering and neuronal protection. It also serves as a developmental marker of retinal ganglion cells (RGCs). In order to study the role of calretinin in the development and regeneration of RGCs, we have studied its pattern of expression in the retina at different developmental stages, as well as during optic nerve regeneration by means of immunohistochemistry. During development, calretinin is found for the first time in RGCs when they connect with the optic tectum. Optic nerves from adult zebrafish were crushed and after different survival times, calretinin expression in the retina, optic nerve tract and optic tectum was studied. From the day of crushing to 10 days later, calretinin expression was found to be downregulated within RGCs and their axons, as was also observed during the early developmental stages of RGCs, when they are not committed to a definite cell phenotype. Moreover, 13 days after lesion, when the regenerating axons arrived at the optic tectum, a recovery of calretinin immunoreactivity within the RGCs was observed. These results indicate that calretinin may play an important role during optic nerve regeneration, Thus, the down-regulation of Calretinin during the growth of the RGC axons towards the target during development as well as during their regeneration after injury, indicates that an increase the availability of cytosolic calcium is integral to axon outgrowth thus recapitulating the pattern observed during development.     

Laminar restriction of retinal macrophagic response to optic nerve axotomy in the rat

Following optic nerve transection, most of the retinal ganglion cells die. Their debris is promptly cleared by phagocytic cells. It is currently not known to what extent peripherally derived macrophages contribute to this activity. Using antibodies OX42 and ED‐1, phagocytic cells were labeled in the retinas of optic nerve lesioned adult rats. To distinguish whether the cells were reactive microglial or macrophagic in origin, blood‐borne monocytes were labeled with fluorescent microspheres while in the systemic circulation. Macrophages invaded the retina, but only in the nerve fiber layer, sparing the ganglion cell and other layers. These macrophages engulfed only the axonal debris from dying ganglion cells, not their degenerating cell bodies. These results indicate that although peripherally derived monocytic cells are recruited into the retrogradely degenerating retina, their role in clearing debris is limited to the optic fiber layer. © 1999 John Wiley & Sons, Inc. J Neurobiol 40: 55–66, 1999     

Expression of PirB Protein in Intact and Injured Optic Nerve and Retina of Mice

The aim of this study was to investigate the expression of PirB protein in intact mice ON (optic nerve) and retina, and to evaluate its change after ON injury. The mouse ON crush model was established. The immunohistochemistry and western blot were used to detect PirB expression. We discovered PirB signals were located as beaded arrangement along the ON long axis in intact ON, disordered in injured ON, and distributed mainly in ganglion cell layer in intact and injured retina. Both PirB expression in injured ON and retina were significantly increased at 1-day post injury (1-dpi), nearly peaked at 7-dpi, but thereafter there was no significant change of them till at least 28-dpi. We concluded the expression of PirB was positive in intact ON and retina, and significantly increased after ON injury. These findings, coupled with previous studies, may imply that PirB is probably a critical molecule in inhibition of axonal regeneration by myelin inhibitors after ON injury.     

Distribution of Mesenchymal Stem Cells and Effects on Neuronal Survival and Axon Regeneration after Optic Nerve Crush and Cell Therapy

Bone marrow-derived cells have been used in different animal models of neurological diseases. We investigated the therapeutic potential of mesenchymal stem cells (MSC) injected into the vitreous body in a model of optic nerve injury. Adult (3–5 months old) Lister Hooded rats underwent unilateral optic nerve crush followed by injection of MSC or the vehicle into the vitreous body. Before they were injected, MSC were labeled with a fluorescent dye or with superparamagnetic iron oxide nanoparticles, which allowed us to track the cells in vivo by magnetic resonance imaging. Sixteen and 28 days after injury, the survival of retinal ganglion cells was evaluated by assessing the number of Tuj1- or Brn3a-positive cells in flat-mounted retinas, and optic nerve regeneration was investigated after anterograde labeling of the optic axons with cholera toxin B conjugated to Alexa 488. Transplanted MSC remained in the vitreous body and were found in the eye for several weeks. Cell therapy significantly increased the number of Tuj1- and Brn3a-positive cells in the retina and the number of axons distal to the crush site at 16 and 28 days after optic nerve crush, although the RGC number decreased over time. MSC therapy was associated with an increase in the FGF-2 expression in the retinal ganglion cells layer, suggesting a beneficial outcome mediated by trophic factors. Interleukin-1β expression was also increased by MSC transplantation. In summary, MSC protected RGC and stimulated axon regeneration after optic nerve crush. The long period when the transplanted cells remained in the eye may account for the effect observed. However, further studies are needed to overcome eventually undesirable consequences of MSC transplantation and to potentiate the beneficial ones in order to sustain the neuroprotective effect overtime.     

Enzyme histochemical changes in retinal ganglion cells and the optic nerve after goldfish optic nerve lesion. A regenerative and hypertrophic phenomena study

After sectioning of the goldfish optic nerve a number of enzyme histochemical changes are observed in the hypertrophied retinal ganglion cells and in the optic nerve. Between one and eighteen days postoperatively an increase in the amount of acid phosphatase reaction product is noted. The enhanced activity decreased to normal first in the optic nerve, followed by the optic tract and tectum. Four days postoperatively higher levels of activity were noted in the hypertrophic retinal ganglion cells for the enzymes NADH tetrazolium reductase, cytochrome oxidase, glutamate dehydrogenase and lactate dehydrogenase. The same enzymes also showed an activity increase in the lesioned optic nerve after four to ten days postoperatively, beginning at the cut and gradually spreading towards the optic tectum. Between fifteen and eighteen days the activity dropped to normal in the hypertrophic retinal ganglion cells, while in the lesioned nerve raised levels of reaction products could be seen till days thirty-five and/or forty-five. It was concluded that the degeneration of the optic pathway is marked by the increase of acid phosphatase activity, whereas the process of regeneration is characterized by an increase of NADH tetrazolium reductase, cytochrome oxidase, glutamate dehydrogenase and lactate dehydrogenase activities. The possible functional implications of these enzymes in the regenerative phenomena are discussed.     

Rat retinal benzodiazepine receptors are controlled by visual cortical mechanisms

[³H]flunitrazepam binding was assayed in retinae of 25-day-old rats subjected either to unilateral enucleation at day 15, to intracranial unilateral cutting of the optic nerve at day 17, or to unilateral ablation of the visual cortex at day 17 postnatally.Unilateral enucleation resulted in an enhanced [³H]flunitrazepam binding in the retina of the remaining eye by 23% (P < 0.002, two-tailed Student t-test) as compared to unoperated controls.In rats with one optic nerve cut shortly before the optic chiasm, benzodiazepine binding in the retina of the lesioned side was significantly higher by 20.4 ± 7.6% (P < 0.02, N = 10, paired test) in comparison to that in the retina with the intact optic nerve.Unilateral visual cortex ablation resulted in a 13% decrease (P < 0.02) in [³H]flunitrazepam binding in the retina contralateral to the brain lesion.In the lesioned rats of all three groups, the retinal benzodiazepine receptors were no longer capable of being modified by light/dark adaptation as is observed in normal rats. Our data suggest that (i) rat retinal benzodiazepine receptors are under a control from the visual cortex, and (ii) the benzodiazepine receptors of both eyes seem to be mutually tuned, presumably via a cortico-retinal feedback loop and an interhemispheric cortico-cortical information transfer.     

Alterations in the morphology of ganglion cell dendrites in the adult rat retina after optic nerve transection and grafting of peripheral nerve segments

Summary Transected ganglion cell axons from the adult retina are capable of reinnervating their central targets by growing into transplanted peripheral nerve (PN) segments. Injury of the optic nerve causes various metabolic and morphological changes in the retinal ganglion cell (RGC) perikarya and in the dendrites. The present work examined the dendritic trees of those ganglion cells surviving axotomy and of those whose severed axons re-elongated in PN grafts to reach either the superior colliculus (SC), transplanted SC, or transplanted autologous thigh muscle. The elaboration of the dendritic trees was visualized by means of the strongly fluorescent carbocyanine dye DiI, which is taken up by axons and transported to the cell bodies and from there to the dendritic branches. Alternatively, retinofugal axons regrowing through PN grafts were anterogradely filled from the eye cup with rhodamine B-isothiocyanate. The transection of the optic nerve resulted in characteristic changes in the ganglion cell dendrites, particularly in the degeneration of most of the terminal and preterminal dendritic branches. This occurred within the first 1 to 2 weeks following axotomy. The different types of ganglion cells appear to vary in their sensitivity to axotomy, as reflected by a rapid degeneration of certain cell dendrites after severance of the optic nerve. The most vulnerable cells were those with small perikarya and small dendritic fields (type II), whereas larger cells with larger dendritic fields (type I and III) were slower to respond and less dramatically affected. Regrowth of the lesioned axons in peripheral nerve grafts and reconnection of the retina with various tissues did not result in a significant immediate recovery of ganglion cell dendrites, although it did prevent some axotomized cells from further progression toward posttraumatic cell death.     

Fine structure of the retino-optic nerve junction in the chicken

The aim of this study is to investigate a fine structure of the retino-optic nerve junction in the chicken. We especially focused on the myelin sheaths and astrocytes in the intraocular optic nerve (ION) and its adjoining parts. A part of the axons of retinal nerve fiber layer (NFL) were myelinated. Ganglion cell axons were ensheathed by loose myelin in the NFL and by a compact one in the ION and optic nerve (ON). Myelin structure changed from loose type to a compact one within the very narrow NFL-ION junction. Loose myelin forming cells are dark type of oligodendrocytes in the retina. From the most peripheral ON to the choroidal part of ION, astrocytes contained abundant microtubules. The optic nerve around the lamina cribrosa is exposed to mechanical force during eye movement. It is suggested that these microtubules may perform the cytoskeletal function. Astrocytes in the retinal part of ION had longer processes filled with abundant gliofilaments. They may provide the mechanical support for the ganglion cell axons, which are exposed directly to intraocular pressure. Although astrocytes in the retinal level of ION extended their processes into the retina, their soma was never found in the retina.