Gradients of ephrin-A2 and ephrin-A5b mRNA during retinotopic regeneration of the optic projection in adult zebrafish

Regeneration of optic axons in the continuously growing optic system of adult zebrafish was analyzed by anterograde tracing and correlated with the mRNA expression patterns of the recognition molecules ephrin-A2 and ephrin-A5b in retinal targets. The optic tectum and diencephalic targets are all reinnervated after a lesion. However, the rate of erroneous pathway choices was increased at the chiasm and the bifurcation between the ventral and dorsal brachium of the optic tract compared to unlesioned animals. Tracer application to different retinal positions revealed retinotopic reinnervation of the tectum within 4 weeks after the lesion. In situ hybridization analysis indicated the presence of rostral-low to caudal-high gradients of ephrin-A2 and ephrin-A5b mRNAs in unlesioned control tecta and after a unilateral optic nerve lesion. By contrast, the parvocellular superficial pretectal nucleus showed retinotopic organization of optic fibers but no detectable expression of ephrin-A2 and ephrin-A5b mRNAs. However, a row of cells delineating the terminal field of optic fibers in the dorsal part of the periventricular pretectal nucleus was intensely labeled for ephrin-A5b mRNA and may thus provide a stop signal for ingrowing axons. Ephrin-A2 and ephrin-A5b mRNAs were not detectable in the adult retina, despite their prominent expression during development. Thus, given a complementary receptor system in retinal ganglion cells, expression of ephrin-A2 and ephrin-A5b in primary targets of optic fibers in adult zebrafish may contribute to guidance of optic axons that are continuously added to the adult projection and of regenerating axons after optic nerve lesion.     

Immunohistochemical localization of CNTFRalpha in adult mouse retina and optic nerve following intraorbital nerve crush: evidence for the axonal loss of a trophic factor receptor after injury

Ciliary neurotrophic factor (CNTF) is important for the survival and outgrowth of retinal ganglion cells (RGCs) in vitro. However, in vivo adult RGCs fail to regenerate and subsequently die following axotomy, even though there are high levels of CNTF in the optic nerve. To address this discrepancy, we used immunohistochemistry to analyze the expression of CNTF receptor alpha (CNTFRalpha) in mouse retina and optic nerve following intraorbital nerve crush. In normal mice, RGC perikarya and axons were intensely labeled for CNTFRalpha. At 24 hours after crush, the immunoreactivity normally seen on axons in the nerve was lost near the lesion. This loss radiated from the crush site with time. At 2 days postlesion, labeled axons were not detected in the proximal nerve, and at 2 weeks were barely detectable in the retina. In the distal nerve, loss of axonal staining progressed to the optic chiasm by 7 days and remained undetectable at 2 weeks. Interfascicular glia in the normal optic nerve were faintly labeled, but by 24 hours after crush they became intensely labeled near the lesion. Double labeling showed these to be both astrocytes and oligodendrocytes. At 7 days postlesion, darkly labeled glia were seen throughout the optic nerve, but at 14 days labeling returned to normal. It is suggested that the loss of CNTFRalpha from axons renders RGCs unresponsive to CNTF, thereby contributing to regenerative failure and death, while its appearance on glia may promote glial scarring.     

Peptide-like immunoreactivity in anuran optic nerve fibers

Unilateral section, crush, or ligation of the optic nerve was performed in Rana pipiens. Following optic nerve disruption, Substance P (SP)-, leucine-enkephalin (LENK)-, cholecystokinin octapeptide (CCK8)-, and bombesin (BOM)-like immunoreactivities were analyzed in the retinae and optic nerves. Peptide-like immunoreactivity developed in the retinal stump of disrupted optic nerves within 1 hour after surgery and was retained until at least 30 days. Peptide-positive staining in the retinal stump of the optic nerves was abolished by preabsorption of each of the antibodies/antisera with the corresponding synthetic substances. No massive peptide-like immunoreactivity was observed in the cerebral stump of the ligated side, nor in the contralateral, nonoperated, optic nerve. No change in the pattern of peptide-like immunoreactivity was apparent in the retina ipsilateral or contralateral to the experimental procedure. The optic tectum contralateral to the surgical procedure displayed those changes in peptide-like immunoreactivity described previously following retinal deafferentation (Kuljis and Karten, '82a, '83a). Peptide-like immunoreactivity in the stump retinad to the surgical procedure occurred in the form of beaded and fibrillar elements often ending in an irregular expansion near the lesion site. Fluorescent double-label antibody methods demonstrated that SP-like immunoreactivity is present in different processes than those containing LENK, CCK8, or BOM. Electron microscopical immunocytochemistry revealed that peptide-like immunoreactivity is contained within unmyelinated and possibly also within myelinated axons in the stump retinad to the traumatic procedure. Radioimmunoassay studies of SP demonstrated a four- to sixfold increase in SP-like content in the retinal stump of ligated nerves, compared with both the cerebral stump and with the contralateral nonoperated optic nerves. These findings demonstrate the presence of peptide-like immunoreactivity in retinal ganglion cell processes, which is compatible with either a posttraumatic expression of previously repressed peptide-like phenotypes, or, most likely, with the existence of various classes of peptide-containing retinal ganglion cells. The latter prospect strongly suggests that peptide-specific subsets of retinal ganglion cells terminate in highly specific laminae in the optic tectum (Kuljis and Karten, '81, '82a-83a) and presumably differ in their physiological role in vision.(ABSTRACT TRUNCATED AT 400 WORDS)     

Amphibian-specific regulation of polysialic acid and the neural cell adhesion molecule in development and regeneration of the retinotectal system of the salamander Pleurodeles waltl

Antibodies specific to the neural cell adhesion molecule (NCAM-total), the 180 × 10³ My component of NCAM (NCAM-180) and polysialic acid (PSA) were used in immunohistochemistry and Western blots to detect the spatiotemporal dynamics of these molecules in development and regeneration of the retinotectal system of Pleurodeles waltl. NCAM-total and NCAM-180 are continuously expressed in the retina, optic nerve, and tectum of the developing and adult salamander. This is also found for the 140 × 10³ My component of NCAM in Western blots of the retina. In the larval retina, PSA is present in the inner plexiform layer (IPL) and a few cells in all nuclear layers. At metamorphosis, PSA expression in the retina strongly increases in the layer of cone photoreceptor somata. Several cells in the inner nuclear layer and Muller cell processes also begin to express PSA. This pattern persists into adulthood. The optic nerve and the tectum are strongly PSA-immunoreactive throughout development. In the adult optic nerve and optic fiber pathway in the brain, PSA expression is selectively downregulated. In the crush-lesioned adult optic nerve, regenerating fibers are NCAM-180-positive but PSA-negative. This demonstrates a molecular difference between growing nerve fibers of Pleurodeles in development and in regeneration. PSA regulation is closely correlated with metamorphosis, thus suggesting that PSA expression may be under hormonal control. Some aspects of PSA and NCAM isoform expression patterns in the retinotectal system of salamanders differ considerably from that of other vertebrates. The substained expression of NCAM isoforms in adult salamanders might be due to secondary simplification (paedomorphosis). © 1993 Wiley-Liss, Inc.     

Early postnatal expression of L1 by retinal fibers in the optic tract and synaptic targets of the Syrian hamster

Previous immunohistochemical studies in mouse, rat, and chick have reported that the expression of the glycoprotein and cell adhesion molecule L1, a member of the immunoglobulin superfamily, shows regulation during development of retina and optic nerve. To extend our understanding of the role of L1 in developing neural circuitry, we have examined L1 expression in the optic tract and thalamic and midbrain synaptic targets of retinal fibers in the early postnatal Syrian hamster, a well-characterized developmental model of the primary visual projection. Metabolic labeling studies reveal that a synaptically targeted, sulfated, and glycosylated form of L1 undergoes rapid axonal transport from the retina. Retinofugal transport of L1 decreases commensurate with the decline in immunoreactivity of retinal fibers in the visual pathway. Retinal ganglion cell axons show intense L1 immunoreactivity as they navigate in highly fasciculated bundles in the optic tract overlying the lateral geniculate body and in the superior colliculus. We found no evidence of L1 immunoreactivity on retinal axon collaterals as they defasciculate from the optic tract and branch into target neuropils. L1 immunoreactivity wanes in optic tract as axon terminal arbors are elaborated in the lateral geniculate body and superior colliculus and as myelination in the visual pathway commences. This pattern of L1 expression suggests that, in the early postnatal period, L1 may support fasciculation of retinal fibers, maintaining them within the optic tract, and that subsequent down-regulation of L1 may facilitate their terminal arborization and myelination.     

Will central nervous systems in the adult mammal regenerate after bypassing a lesion? A study in the mouse and chick visual systems

We determined whether or not optic axons in the adult mammalian retina would regenerate well if allowed to bypass a lesion scar. In one series we produced microlesions with fine needles in the ganglion cell fiber layer of adult mouse retinas and later examined the retinas as silver-stained flat mounts to observe the behavior of optic axons that bypassed the lesion. Such axons continued to grow abortively, i.e., grew randomly and for only short distances, whether growing within a sector of Wallerian (anterograde) degeneration or in the neighboring zone of intact optic axon bundles. In a second series we produced optic nerve crushes in adult mice and observed the behavior of optic axons growing retrograde into the retina. These fibers similarly grew abortively whether in a zone of intact fiber bundles or when a retinal lesion was produced with the crush, in the sector of Wallerian degeneration. Retinal lesions in newly hatched chicks produced a comparable picture of abortive (short-distance) growth, but the optic and centrifugal fibers had a greater tendency to remain oriented within the ganglion cell fiber layer than did mouse axons. This improved orientation may be the consequence of the greater number of optic fibers in the chick retina and hence the greater opportunity for nonspecific contact guidance. The results indicate that blockage (by a lesion scar or myelin debris) and hypoxia are not the key causes of regenerative failure, as regeneration failed even when those factors were minimal.     

The monoclonal antibody E587 recognizes growing (new and regenerating) retinal axons in the goldfish retinotectal pathway

E587 is a new monoclonal antibody against a 200 kDa cell-surface glycoprotein in the fish retinotectal pathway. The E587 antigen probably belongs to the class of cell adhesion molecules, and more specifically, to the family of L1-like molecules. The immunopurified protein is recognized by the antibody against the HNK1/L2 sugar epitope (associated with most cell adhesion molecules) and by a polyclonal antiserum against chick G4, which is related to the cell adhesion molecule L1 in mouse. Moreover the NH2-terminal sequence of E587 shows similarity with L1 and Ng-CAM. The E587 immunostaining pattern in the fish retinotectal pathway suggests that the E587 antigen is a growth-associated molecule on fish retinal axons. In fish embryos, all retinal axons are labeled. In adult fish, however, only the young axons from newly added ganglion cells carry E587 staining. After optic nerve transection (ONS) and retinal axonal regeneration, all axons reexpress the E587 antigen into their terminal processes in the tectal retinorecipient layers. The reexpression of the E587 antigen is temporally regulated, and E587 immunoreactivity declines by 7 months and disappears at 12 months after ONS. We hypothesize that the E587 antigen may mediate axon-axon associations. In its restricted appearance on young axons in normal adult fish, it may contribute to the selective fasciculation of the newest axons with young axons and thus participate in the creation of the age-related fiber organization in the fish optic nerve.     

Plasticin,a newly identified neurofilament protein,is preferentially expressed in young retinal ganglion cells of adult goldfish

The adult goldfish retina and optic nerve display continuous growth, plasticity, and the capacity to regenerate throughout the animal's life. The intermediate filament proteins in this pathway are different from those in adult mammalian nerves, which do not continuously grow or normally regenerate. One novel intermediate filament protein of the goldfish visual pathway is plasticin, which is synthesized in ganglion cells and transported into the optic nerve. Using specific polyclonal antibodies raised against a plasticin fusion protein, we investigated the distribution of this protein in the normal retina and nerve and in the retina and nerve following optic nerve crush. In the normal pathway, plasticin was localized predominantly to the axons of very young ganglion cells; however, there was considerable immunoreactivity in older axons as they approach the chiasm. In addition, following optic nerve crush, all ganglion cell somata and their axons proximal to the crush site became equally immunoreactive. The results suggest that plasticin may contribute to axonal growth, plasticity, and regeneration. © 1994 Wiley-Liss, Inc.     

Serotonin-like immunoreactivity in the adult and developing retina of the leopard frog Rana pipiens

Recent work in nonmammalian vertebrate retinas has suggested that other cell types besides the generally accepted amacrine cells may contain serotonin. We have used immunocytochemical methods to study serotonin-like immunoreactivity (5-HTLI) in the retina of the developing and mature frog Rana pipiens. In the adult, two types of serotonin immunoreactive (5-HT-ir) cells were found in the inner nuclear layer (INL) of the retina. Additionally, a large population of cells in the retinal ganglion cell layer (RGCL) had 5-HTLI. These cells were grouped into three types based on their soma size and their primary dendritic branching pattern. The optic nerve fiber layer was also intensely stained with serotonin antisera although staining intensity decreased progressively as the fibers approached the optic nerve head. Severing the optic nerve resulted in 5-HT-ir elements that extended up the optic nerve shaft from the lesion site toward the retina. Both regional and temporal changes in the pattern of 5-HTLI were seen. In middle regions of retina, approximately 30% of the cells in the RGCL were 5-HT-ir. Nasal and temporal regions of central retina had significantly fewer 5-HT-ir cells. Early in development only scattered cells in the RGCL were 5-HT-ir. As the animals matured there was an increase in both the proportion and the staining intensity of these cells. Our results suggest that in studying the function and development of the visual system in this animal, the role of serotonin must be examined. © 1993 Wiley-Liss, Inc.     

Growth of retinal ganglion cell axons following optic nerve crush in adult hamsters

Regrowth of retinal ganglion cell axons was examined 2 to 60 days after intraorbital optic nerve crush lesions in adult hamsters. Anterograde axonal transport of intraocularly injected wheat germ agglutinin-horseradish peroxidase conjugate was used to label the axons after specific postinjury time periods. Labeled axons were present in the region of the optic nerve lying between the eye and the crush site at all times, but their numbers appeared to decrease with increasing survival time. Labeled axons were first detected in the segment of optic nerve lying distal to the crush site 1 week after injury and had extended as far as 2.3 mm beyond the crush site by 60 days postinjury, growing at a rate similar to that at which the collateral branches of developing ganglion cell axons extend into their targets. Although most axons failed to regrow after these lesions, the slow reextention exhibited by members of a small population of axons indicates that the degenerating adult mammalian optic nerve provides an adequate environment for a particular mode of regrowth by injured axons of the central nervous system.     

Adult retinal ganglion cells retain the ability to regenerate their axons up to several weeks after axotomy

The present work was to elucidate whether the ability of adult central neurons to regrow their lesioned axons is retained for long periods of time. Using the rat retina as an experimental paradigm, the optic nerve was lesioned by crush in situ. Up to 6 weeks after the trauma, the optic nerve (ON) was again exposed and transected close to the first lesion and autologous sciatic nerve segments were anastomosed at the ocular ON stump. Alternatively, the retina corresponding to the lesioned ON was dissected for in vitro cultivation 1-6 weeks after the crush-axatomy was applied. Both experimental strategies revealed a regrowth of the lesioned retinal ganglion cell (RGC) axons. When peripheral nerve (PN) segments were grafted without previous ON crush, axon stumps started to reelongate and to penetrate the grafted piece of nerve 6 days later. In contrast, when the PN graft was apposed to the ON stump 1-6 weeks after crush, it was penetrated by regrowing axons within 24 hr. Maximal numbers of regenerating axons were observed if transplantation occurred within the first week after the crush. The numbers of axons decreased progressively if transplantation was performed later than 1 week postcrush and approximated zero values at the 6th week. When the noncrushed retina was explanted and cultured in vitro in a chemically defined, serum-free medium, there was almost no extending fiber. In contrast, explantation of the retina for which the ON had been precrushed in situ resulted in massive regrowth of RGC axons. The numbers of regenerating axons and their temporal changes paralleled those described for the transplantation experiments.(ABSTRACT TRUNCATED AT 250 WORDS)     

Expansion of the ipsilateral retinal projection in the frog brain during optic nerve regeneration: Sequence of reinnervation and retinotopic organization

The sequential reinnervation and distribution of optics axons in diencephalic and mesencephalic targets was studied after crushing the optic nerve in 37 adult Rana pipiens. Following intravitreal injection of ³H-proline at various times after nerve crush the distribution of regenerating optic axons was traced using autoradiographic methods. The maximal distribution of regenerating axons was reached between 6 and 8 weeks after optic nerve crush. On the contralateral side of the brain, the distribution of fibers was similar to the normal projection. Ipsilaterally, silver grain density was greater than normal in the optic tract and projections were expanded to all optic targets on this side of the brain. These abnormal projections were sustained for a least 6 months after nerve crush. The sequence of reinnervation of targets on both sides of the brain differed from normal development. Unlike development, regenerating optic axons were found in the ipsilateral optic tract prior to the time they were found on the contralateral side of the brain. Also unlike development, regenerating axons did not begin to reinnervate targets in the anterior thalamus until several weeks after reinnervation of the posterior thalamus and tectum had begun. The expanded distribution of regenerating axons within optic targets on the ipsilateral side of the brain became evident at the time optic axons first invaded each area. Most optic axons appeared to regenerate from the point of nerve crush. The retinal stump of the crushed nerve was filled with labeled axons in all six frogs given intravitreal ³H-proline injections between 1 and 7 days after nerve crush. In addition, using a modified Fink-Heimer method, few degenerating axons were found in the retinal stump of four frogs sacrificed between 2 and 8 days after optic nerve crush. In ten frogs studied between 3 and 6 months after nerve crush, horseradish peroxidase (HRP) was placed on different portions of the tectum ipsilateral to the crush. In each case HRP was retrogradely transported to ganglion cells in both retinae. The cells labeled in the ipsilateral retina corresponded in position to the same region of the contralateral retina although many fewer cells were labeled ipsilaterally. Cutting the optic tract on the side opposite the HRP placement did not affect the results. No ganglion cells were labeled in the ipsilateral retina of two frogs not receiving optic nerve crush. These results show that axons from all parts of the retina regenerate to the ipsilateral side of the brain during optic nerve regeneration and the distribution of these misrouted axons, at least to the tectum, overlaps the intact distribution from the other eye. Differences between development and regeneration in the patterns of growth of optic axons may be related to this anomaly.     

Regeneration of peptide-containing retinofugal axons into the optic tectum with reappearance of a substance P-containing lamina

Twenty-five specimens of Rana pipiens were subjected to a unilateral crush of the optic nerve. Substance P (SP)-, leucine enkephalin (LENK)-, cholecystokinin octapeptide (CCK8)-, and bombesin (BOM)-like immunoreactivities were analyzed in the retinae, optic nerves, and optic tecta, 9 days to 9 months postoperatively, by means of immunohistochemical methods. Peptide-like immunoreactivity was observed in axons within the optic nerve stump retinal to the crush, as in previous studies (Kuljis and Karten, '83b, Kuljis et al., '84). Peptide-containing retinofugal axons began traversing the lesion site between 10 and 20 days postoperatively, in progressively increasing numbers. Ten to 20 days following crush of the optic nerve SP-, LENK-, and CCK8-containing axons could be found in the cerebral stump of the optic nerve and in the optic chiasm, advancing to the side of the brain deafferented by the crush. The number of axons displaying peptide-like immunoreactivity within the optic nerve, retinal or cerebral to the crush, and within the optic chiasm gradually decreased after 2-3 months. The optic nerve contralateral to the procedure displayed only occasional isolated peptide-containing fibers, as in normal optic nerves. The retinae ipsilateral and contralateral to the crush exhibited no change in the normal pattern of peptide-like immunoreactivity, including the absence of demonstrable peptide-like immunoreactivity in the somata of retinal ganglion cells. The optic tectum deafferented by the procedure underwent modifications in the pattern of peptide-like immunoreactivity identical to those reported following unilateral eye enucleation (Kuljis and Karten, '82a, '83a). The patterns of LENK-, CCK8-, and BOM-like immunoreactivities in the tectum were identical to those following irreversible retinal deafferentation as long as 9 months postoperatively. SP-like immunoreactivity, however, was gradually restored in layer 11 of Ramón y Cajal ('46; layer D of Potter, '69) of the superficial (retinorecipient) neuropil 4-6 months postoperatively. The persistence of lamina-specific depletion patterns of LENK-, CCK8-, and BOM-like immunoreactivities in reafferented tecta represents a puzzling observation. The latter findings contrast sharply with the recovery of SP-like immunoreactivity, which occurs long after apparently complete restitution of the retinofugal projection, as shown by anatomical (Stelzner et al., '81), physiological (Maturana et al., '59), and behavioral (Sperry, '44) methods.(ABSTRACT TRUNCATED AT 400 WORDS)     

Distribution of the phosphorylated form of microtubule associated protein 1B in the fish visual system during optic nerve regeneration

Microtubule associated proteins are a heterogeneous group of proteins that have been implicated in regulating microtubule stability. They play an important role in the organisation of the neuronal cytoskeleton during neurite outgrowth, plasticity and regeneration. The fish visual system presents a considerable degree of plasticity. Thus, the retina grows continually throughout life and the optic nerve regenerates after crush. In the present study, we compared the distribution of the microtubule associated protein 1B in its phosphorylated form (MAP1B-phos) in the normal adult fish visual system with that observed during optic nerve regeneration after adult optic nerve crush using a specific monoclonal antibody mAb-150. Expression of MAP1B-phos was observed in some ganglion cell somata and in developing, growing axons within the control optic nerve. Few immunoreactive terminals were seen in the control optic tectum. After optic nerve crush, we found additional MAP1B-phos expression in regenerating axons throughout the visual system. Our results demonstrate that MAP1B-phos is present in growing and regenerating axons of fish retinal ganglion cells, which suggests that the phosphorylated form of MAP1B may play an important role in developmental and regeneration processes within the fish central nervous system.     

Tenascin-R inhibits regrowth of optic fibers in vitro and persists in the optic nerve of mice after injury

Tenascin-R, an extracellular matrix constituent expressed by oligodendrocytes and some neuronal cell types, may contribute to the inhibition of axonal regeneration in the adult central nervous system. Here we show that outgrowth of embryonic and adult retinal ganglion cell axons from mouse retinal explants is significantly reduced on homogeneous substrates of tenascin-R or a bacterially expressed tenascin-R fragment comprising the epidermal growth factor-like repeats (EGF-L). When both molecules are presented as a sharp substrate border, regrowing adult axons do not cross into the tenascin-R or EGF-L containing territory. All in vitro experiments were done in the presence of laminin, which strongly promotes growth of embryonic and adult retinal axons, suggesting that tenascin-R and EGF-L actively inhibit axonal growth. Contrary to the disappearance of tenascin-R from the regenerating optic nerve of salamanders (Becker et al., J Neurosci 19:813-827, 1999), the molecule remains present in the lesioned optic nerve of adult mice at levels similar to those in unlesioned control nerves for at least 63 days post-lesion (the latest time point investigated), as shown by immunoblot analysis and immunohistochemistry. In situ hybridization analysis revealed an increase in the number of cells expressing tenascin-R mRNA in the lesioned nerve. We conclude that, regardless of the developmental stage, growth of retinal ganglion cell axons is inhibited by tenascin-R and we suggest that the continued expression of the protein after an optic nerve crush may contribute to the failure of adult retinal ganglion cells to regenerate their axons in vivo.     

Effect of different optic nerve lesions on retinal ganglion cell death in the frog Rana pipiens

Following optic nerve crush in various species of frog, a proportion of the retinal ganglion cells re-establishes functional contact with the optic tectum. However, as much as 50% of the retinal ganglion cells die during this process. The determinants of an individual ganglion cell's fate have not been established. In this study of Rana pipiens, cell survival after optic nerve crush was compared with that after nerve cut followed by stump separation, a procedure that considerably delayed entry of optic axons to the brain. It was also ascertained, in the case of delayed ingrowth, whether application of nerve growth factor immediately after lesion influenced the cell death process. This study confirmed that retinal ganglion cell death is a relatively late event in regeneration, because in several animals where anterograde HRP labeling demonstrated regenerating axons within the tectum, no cell death had occurred. There was no statistically significant difference in cell death at 75 days after lesion between animals receiving nerve crush and those receiving nerve cut with stump separation, even though most crush animals had regenerated a complete visual projection, whereas most nerve cut animals had not. The application of NGF did not influence the level of cell death at 75 days after lesion. These results suggest that contact of optic axons with the optic tract or tectum is not necessary for retinal ganglion cell death to occur. However, this does not necessarily mean that contact with the brain is not involved with cell death during regeneration following nerve crush because it is possible that the mechanisms of cell death are different when axons are prevented from regenerating. Further investigations are therefore required to establish the reasons for this cell death.     

Glial cells in degenerating and regenerating optic nerve of the adult rat

The glial cell reaction both in degenerating and regenerating adult rat optic nerve was studied by immunohistochemistry and electron microscopy. Degeneration in the optic nerve was achieved by complete transection, and the retinal stump was then analyzed. The regeneration was observed by autotransplantation of a sciatic nerve segment to the transected retinal stump. In both cases, optic nerve axons were labeled anterogradely with rhodamine, followed by immunohistochemical staining. Glial fibrillary acidic protein-positive astrocytes covered the transected end of degenerating optic nerve, whereas in the regenerating optic nerve they enwrapped axonal bundles emerging from the optic nerve stump and migrated together into the transitional zone intervening between the retinal stump and graft. In electron microscopy, direct attachment of astrocyte and Schwann cell was found within the transitional zone, whereby these cells were holding axons between them. Decrease of 04 immunoreactivity, which labels oligodendrocytes, was apparent in the transected end of retinal stump during the regeneration. The ED1 -positivity, which labels microglia/macrophages, was found in cells accumulated in the transitional zone of degenerating optic nerve, whereas during regeneration, ED1-immunoreactive cells were also distributed in the retinal stump. These results suggest that astrocytes, usually considered to interfere with optic nerve regeneration, change their characteristics in the presence of peripheral nerve graft and guide the regenerating axons in cooperation with Schwann cells. The response of oligodendrocytes and microglia/macrophages may also be modulated by peripheral nerve.     

Studies of the early stages of optic axon regeneration in the goldfish

We have studied the early stages (4-14 days) of axonal regeneration following intraorbital optic nerve crush in the goldfish. We used 3H-proline autoradiography to anterogradely label and visualize the growing axons and wheat germ agglutinin-conjugated horseradish peroxidase (WGA:HRP) for retrograde labeling to determine the cells of origin of the earliest projections. The first retinal ganglion cells (RGCs) that could be retrogradely filled from the optic tract, following optic nerve crush, were in the central retina and were seen at 8 days postoperative. More peripheral cells were only labeled with longer postcrush survival periods. Thus, the first axons to regenerate past the lesion were from central RGCs. The axons of these cells extended into the cranial nerve stump between 4 and 5 days postcrush and entered the nerve as a fascicle, which travelled just beneath its surface. Studies of nerve cross sections from animals at 5-8 days postoperative demonstrated that initial outgrowth was not confined to any particular locale within the nerve although the early fibers appeared to avoid its temporal aspect. When the regenerating axons reached the optic tract they remained in fascicles but left the surface to run along the medial, deep portion of the tract, immediately adjacent to the diencephalon and pretectum. The positions occupied by the earliest-regenerating axons in the optic nerve were variable and not always appropriate for their central retinal origin. However, the abrupt change in growth trajectory as the fibers entered the optic tract brought them into the areas of the visual paths that are occupied by central axons in intact animals. We suggest that this change in position is related to both changes in the structural organization of the intracranial visual paths and to possible axon guidance signals in the region of the nerve-tract juncture.     

The course of axons of retinal ganglion cells within the optic nerve and tract of the chick (Gallus gallus)

Small laser lesions placed in the posthatch chicken retina resulted in axotomy and then death of all ganglion cells located in a sector peripheral to the primary damage. With the use of silver techniques, the patterns of degenerating retinal fibers in the optic nerve, chiasm, and optic tract were examined. In the proximal part of the optic nerve, radial retinal lesions resulted in a sheet of degenerating axons along the rostrocaudal extent of the nerve. The position of degenerating axons was related to the site of their entry in the optic nerve head with an overlapping distribution of degenerating fibers entering the optic nerve head from equivalent points from the temporal and nasal sides. In the optic chiasm, the distribution of fibers was similar to that seen in the proximal part of the optic nerve. In the optic tract there was a similar mixing of fibers from opposite sides of the retina. The ventral, nasal and temporal retinal fibers lay in the superficial part of the tract whereas the fibers from the nasal and temporal dorsal retina ran in the deeper, medial aspect of the tract. The central-to-peripheral axes of the retina were mapped along the rostrocaudal axis of the tract. As the tract approached the tectum degenerating fibers from single retinal lesions did not always remain together. In the case of a lesion in the ventral nasal retina, degenerating fibers split into two bundles located at opposite ends of the tract only to reunite at their terminal regional at the caudal pole of the tectum.(ABSTRACT TRUNCATED AT 250 WORDS)