Ganglion cells in retinae transplanted to newborn rats

Axon-target interactions maintain synaptic gene expression in retinae transplanted to intracranial regions of the rat

In the present study we examined the effects of optic axon-CNS target interactions on gene expression in the rat retina. These studies took advantage of a transplantation paradigm that allowed us to assay gene expression in retinae transplanted to different intracranial locations in the neonatal rat that either promoted (dorsal midbrain) or precluded (cerebral cortex) the formation of retino-collicular connections. Using in situ hybridization experiments, we observed that transplantation to the dorsal midbrain resulted in a relatively normal pattern of nicotinic acetylcholine receptor (nAChR) beta-3 subunit and glutamate receptor 3 (GluR3) gene expression. In contrast, retinae transplanted to the cerebral cortex (which did not result in normal retino-collicular interactions) showed a dramatic reduction in nAChR beta-3 subunit and GluR3 gene expression. These results agree with those obtained in the adult goldfish retina, where it has been demonstrated that an optic nerve-optic tectum interaction is responsible for the re-induction nAChR and NMDA receptor gene expression during optic nerve regeneration. Taken together, these results support the hypothesis that proper axon-target interactions are required for maintenance of nAChR and glutamate receptor gene expression in the mature vertebrate retina.

The pupillary light response: functional and anatomical interaction among inputs to the pretectum from transplanted retinae and host eyes

Pupilloconstriction to light can be mediated in rats through direct illumination of retinae previously transplanted to intracranial locations. Transplant-driven and normal pupillary light responses are stable under optimal testing conditions, and parameters describing the response can be quantified precisely. The present study demonstrates the interaction between transplant-driven and normal pupillary response patterns. When stimuli are presented concurrently to a transplanted retina and to the remaining eye in host rats, a greater degree of pupilloconstriction occurs than when either the transplanted or the host eye is illuminated independently. This suggests that transplant and host retinal inputs act in concert to determine pupil diameter. The second portion of this study investigates the pattern of retinal input to the pretectum to determine if a structural basis for such functional interactions may exist. Crossed and uncrossed retinal projections to the olivary pretectal nucleus occupy non-overlapping regions of this bilaterally represented nucleus in normal rats, with a greater number of optic axons directed to the contralateral olivary pretectal nucleus. Retinae transplanted to the midbrain of neonatal rats, from whom the contralateral eye had been removed, also project to the olivary pretectal nucleus at maturity. By contrast with the normal pattern of segregated retinal inputs, however, the terminal fields of transplant axons were found to overlap extensively with the retinal projection from the remaining host eye. In addition, the relative proportion of transplant axons directed to the ipsilateral and contralateral olivary pretectal nucleus varied among animals. The lack of spatial segregation between inputs from transplant and host sources and the relative proportion of ipsilateral and contralateral transplant axons together may represent a structural basis for the observed functional interactoin of these inputs to the neural circuit subserving pupilloconstriction to light. These features may also relate to the marked improvements in transplant-mediated responses that frequently occur when optic input from the remaining host eye is eliminated. The results presented here, together with our previous transplant studies, show that this preparation can be used to provide insight into more general questions as to the dynamic interactions that occur between converging sensory inputs in the generation of integrated output responses.

The pupillary light response: assessment of function mediated by intracranial retinal transplants

We have adapted a pupillometry measurement system to test the functional efficacy of retinae previously transplanted over the midbrain of neonatal rats in mediating a pupillary light reflex in the host eye. This has permitted us to examine factors influencing various parameters of the response, and to study transplant-mediated responses in comparison with responses mediated by way of the normal consensual pathway. Despite the unusual location of these transplanted retinae and the absence of supportive tissues normally associated with retinae in situ, it is clear that pupilloconstriction in the host eye can be elicited by transplant illumination. Under the optimal conditions here defined, response parameters for individual animals were stable with repeated testing over extended periods. When considered as individual cases, response amplitude, constriction rate and response latency were intensity dependent, although responses elicited by transplant illumination were less sensitive than normal, typically by 2-3 log units. Large-amplitude transplant-mediated pupillary responses could, however, be elicited repeatedly throughout long trains of stimuli, unlike normal responses, which rapidly failed to recover to baseline under similar test conditions. Finally, even though some cellular elements of the visual cycle are absent in transplanted retinae, pupilloconstriction in the host eye could be elicited repeatedly by transplant illumination as long as two years after transplantation took place. These observations indicate the applicability of this preparation as an assay for the effects of experimental manipulations on information processing and response plasticity in the visual system, and as a tool for examining, in general, the necessary conditions for optimal function of grafts that work by synthesizing and relaying neural signals.

Co-transplantation of embryonic retina and retinal pigment epithelial cells to rabbit retina

The retinal pigment epithelium (RPE) is important for normal development of the neural retina. We sought to investigate whether cografting RPE cells affected the differentiation and survival of retinal grafts. Pigmented embryonic day 16 (E16) rabbit retina was dissected either with or without attached RPE and injected into a lesion site in retinas of young adult rabbit hosts. Each host obtained a pure retina graft in one eye and a retina/RPE cograft in the other. Animals were sacrificed after 4, 8 and 12 weeks. After 4 weeks, grafts (1-2 mm in diameter) were seen in both experimental groups at the lesion site or in the subretinal space. However, 8 and 12 weeks after transplantation, the graft survival rate decreased. The grafts developed cell layers in folded sheets and many rosettes (a rosette consists of photoreceptors and cells of other retinal layers around a central lumen defined by an outer limiting membrane). Cografts of retina with RPE had areas of more distinct cell lamination than transplants of pure retina. Grafted RPE cells were organized in clusters of cells surrounded by extracellular matrix and often associated with blood vessels. If the extracellular matrix of RPE cell clusters was outside the rosettes close to inner retinal layers in the graft, transplant Müller cell endfeet developed an inner limiting membrane. Müller cell endfeet could also be observed in subretinal transplants attached to the denuded Bruch's membrane of the host. In 12-week grafts, when RPE cell clusters were inside rosettes, the surrounded photoreceptors survived better. No RPE effect could be seen if single RPE cells were dispersed among retinal donor cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Visual information processing by intracerebral retinal transplants in rats

We have developed a simple system involving the implantation of retinae over the midbrain of rodents to examine whether, in a clearly defined system such as the primary optic pathway, it is possible to re-create circuits lost as a result of injury or developmental disorder. For much of the work, immature rat hosts have been used, in part to maximise optimal conditions and to provide a baseline for similar transplants in adults. In this review we summarise the sequence of studies that has led us to the conclusion that transplanted retinae are capable not only of differentiating and responding to light but also of relaying luminance information to visual centres of the host brain where appropriate behavioural responses are elaborated.

Optic nerve degeneration induces the expression of MHC antigens in the rat visual system

The brain has long been considered to be an immunologically privileged site. However, privilege is not absolute, as has been shown by the inability of foreign tissue grafts to survive indefinitely in the brain. The rejection of this tissue is accompanied by the upregulation of major histocompatibility complex (MHC) antigen expression. Therefore it is essential to define conditions that influence the expression of these antigens in the brain, especially since such a definition may further the understanding of disease processes that lead to the autoimmune destruction of the central nervous system. Here we show that both MHC class I and class II antigens are expressed within 1 or 2 days of eye removal by cells showing the morphological characteristics of microglia. Expression is seen along the optic pathway and within the brainstem centers to which optic axons project. In the early stages of the reaction, MHC class I antigen expression is seen throughout the optic pathway, including the terminal distribution areas of the subcortical visual centers, while MHC cells class II are localised mainly to degenerating myelinated fiber systems. These changes are not accompanied by any alteration in the integrity of the blood-brain barrier. During the second week postlesion, class I positive cells are found beyond the confines of the degenerating pathways, while class II positive cells are seen within regions such as the stratum griseum superficiale of the superior colliculus, where few myelinated axons are present. There is subsequent diminution of MHC positive cells, but a small number of cells are still seen 60 days post-lesion. Focal lesions within the eye show that at early survival times, while class I MHC positive cells are distributed throughout the nerve, class II positive cells are largely absent from the unmyelinated segment of the nerve. Retrograde changes in the retina after nerve section are accompanied only by MHC class I antigen expression. These observations show that neural degeneration is accompanied by a rigid sequence of events involving expression of MHC antigens by microglia. If foreign antigens were present in the brain while these events were taking place, it is possible that such antigens would be recognised and destroyed by the host immune system.

Effect of proteoglycan purified from rat superior colliculus on the survival of murine retinal ganglion cells

Recently, Schulz and coworkers purified a chondroitin sulfate proteoglycan from the superior colliculus of the neonatal rat which promoted survival of neonatal rat retinal ganglion cells in vitro. The present work tests whether this factor supports the survival of axotomised retinal ganglion cells in vivo. To this effect, murine retinae 15 and 20 days after conception were explanted to the chorioallantoic membrane of live chicken embryos. The explants, which were left in the egg for 1, 2 or 7 days, differentiated and grew according to a normal timetable. Purified proteoglycan from neonatal rat superior colliculus was applied daily to one group of retinae while a control group received Ham's F-10 medium. Results indicated that application of proteoglycan resulted in the preferential survival of large cells in the ganglion cell layer, namely ganglion cells, for up to 7 days post-explantation. In addition, the proteoglycan had a significant short-term anti-traumatic effect on the ganglion cell layer of explants by causing a 72% decrease in the number of dead cells relative to controls 1 day post-explantation. It was concluded that the chondroitin sulfate proteoglycan purified from the superior colliculus of the neonatal rat promotes the survival of fetal and neonatal murine retinal ganglion cells in retinae explanted to the chorioallantoic membrane of the chick.

Explantation of fetal murine retinae to the chorioallantoic membrane of the chicken embryo

A technique is here described for the culture of mammalian retinal explants on the chorioallantoic membrane of the developing chicken embryo. As an integral part of the central nervous system, the mammalian retina is characterised by its highly organised laminar structure and developmental timetable. Study of its prenatal development is, however, difficult to undertake in utero. In an attempt to render the organ of vision more accessible experimentally, fetal mouse retinae were explanted across major species barriers to the live chorioallantoic membrane of the chick. From 26 experiments, 128 explants (70% of the total) were recovered and 27 possessed a cytomorphology apparently identical to that of age-matched controls. The surviving retinae were analysed using a specifically devised set of criteria and they had developed a normal laminar structure (ganglion cell, inner plexiform, inner nuclear, outer plexiform and outer nuclear layers) but increased numbers of pyknotic profiles were present and somal sizes in the ganglion cell layer were significantly smaller. Such patterns have been obtained in other studies, both in vivo and in vitro, in which retinae had no access to their major targets in the brain, the superior colliculus and lateral geniculate nucleus. Explantation to the chorioallantoic membrane is thus a viable alternative for experiments requiring tissue isolation from natural surroundings since the explants are accessible for manipulation and observation while interacting with the host chick embryo. Furthermore, the technique allows examination of retinal differentiation, offering the opportunity to answer a number of important questions regarding development in the central nervous system.

Development of choline acetyltransferase-immunoreactive neurons in normal and intracranially transplanted retinas in rats

Retinas from embryonic day 14 (E14) Sprague-Dawley rats were transplanted to the tectum of newborn (P0) recipient rats, and the distribution pattern of choline acetyltransferase immunoreactivity (ChAT-I) in developing transplants was studied and compared with those observed in the retinas of normal developing rats. In normal retinas, ChAT-I cells were first identified in restricted regions in the ganglion cell layer (GCL) at P4, but were found to cover the entire GCL by P6. A second population of ChAT-I cells was detected in the inner nuclear layer (INL) at P8, and they were observed in most parts of the INL on P10 when two immunoreactive sublaminae began to appear in the inner plexiform layer (IPL). The adult pattern of having two distinct populations of ChAT-I cells, organized in mirror symmetrical fashion in the inner retinal layers was basically established by P12. The time course of development and overall distribution pattern of ChAT-I cells in developing retinal transplants on the whole were very similar to those observed in normal retinas. The first identification of these cells and the establishment of their final distribution pattern were made at stages corresponding to P4 and P12 of normal developing retinas respectively. However, ChAT-I somata were located in the INL at a much earlier stage compared with their counterparts in the normal retina, and a transient population of immunoreactive cells with their processes extending to retinal layers other than the IPL was observed in some transplants from P6 to P10. These features were not observed in normal developing retinas. These results suggest that the development of cholinergic neurons, especially the expression of their characteristic antigen and their final distribution pattern is largely determined by programmes which are intrinsic to the original retinal tissue, despite some minor deviation or variation in the developmental process which may occur under certain abnormal conditions.

Structural features of neurons in whole grafts of the rat inferior colliculus

The inferior colliculus (IC) is a midbrain structure that receives ascending auditory input from brainstem nuclei via the lateral lemniscus, sends efferent fibers to the medial geniculate body of thalamus and receives descending projections from auditory cortex. In the rat, the IC consists of dorsal and external cortices surrounding the central nucleus of IC (CNIC) which is populated by discoid and stellate neurons; the CNIC has a laminar appearance arising from organization of lemniscal fibers and processes of discoid cells. The IC of adult rats was chosen for implantation of whole grafts of E16-17 caudal tectum into unilateral lesion sites. Dendritic and somal architecture of graft neurons was examined 1 to 4.5 months following implantation using rapid Golgi, HRP and Nissl methods. The CNIC of rat is dominated by principal neurons with relatively flattened dendritic fields. In grafts of caudal tectum the most common neuron class observed possesses flattened dendritic arbors which often parallel one another. These neurons also resemble CNIC neurons of host tissue adjacent to the graft border. Spine formations appear on both proximal and distal dendrites of this neural type in both normal and implanted tissues. In addition, comparable somal features of graft neurons include ovoid or fusiform shapes with regular nuclear membranes as found in the normal colliculus. In Golgi stained material fewer stellate class neurons appear as in the normal CNIC, although stellate cell classes are more abundant in the pericentral areas of normal tissue. Both neuron populations are retrogradely labelled in graft and normal IC after HRP injection into the medial geniculate body. These features suggest that the graft core typically consists of prototypic CNIC cells. Other features of neuron and glial cell density vary in graft material which also shows a complex network of vasculature. These results demonstrate that whole grafts of caudal tectum placed into the inferior colliculus can form organized neural architecture similar to the normal CNIC. The somal, dendritic and spine features of these neurons form a potential substrate for connectional and functional properties which establish this preparation as suitable for further investigation as a model for development and recovery of function in the central auditory system.

Proximity as a factor in the innervation of host brain regions by retinal transplants

Embryonic mouse retinae transplanted to a variety of locations within the rostral midbrain of neonatal rats exhibit selective innervation of host visual nuclei when studied at maturity. Some of these nuclei (superior colliculus, nucleus of the optic tract, dorsal terminal nucleus) usually receive extensive transplant projections, others are innervated partially (dorsal division of the lateral geniculate nucleus, olivary pretectal nucleus, medial terminal nucleus), while a few (ventral division of the lateral geniculate nucleus, suprachiasmatic nucleus, intergeniculate leaflet) are not innervated at all. The selectivity of this innervation is largely independent of the transplant's position within the rostral brainstem, while the density of innervation of individual nuclei depends in part upon the proximity of the transplant to the nucleus and upon whether the host retinal projection to that nucleus is present or absent. These findings provide a foundation for further studies of the behavioral capabilities of retinal transplants, for developmental studies of factors responsible for the establishment of normal neural projections, and for examination of the immunological consequences of transplantation.

Patterns of immune rejection of mouse neocortex transplanted into neonatal rat brain, and effects of host immunosuppression

We studied the histological and immunological characteristics of graft rejection in the rodent central nervous system (CNS) using embryonic mouse neocortex transplanted into the CNS of neonatal rats. Grafts from animals aged 8-145 days (n = 210) were examined using standard histological techniques for demonstrating cell morphology and fiber projections. Immunohistochemical techniques were used to identify graft projections into the host CNS. The incidence of graft rejection was 18% for animals between 18 and 30 days of age, but increased abruptly to 73% for animals older than 30 days. No graft rejection was seen in animals younger than 18 days. In a smaller group of xenograft recipient rats sacrificed at specific time points before and after one month of age, detailed immunohistochemical studies were performed to correlate the histological appearance of the graft with the level of major histocompatibility complex (MHC) class I and II immunoreactivity, and microglial, astrocytic and lymphocytic staining within the graft and host brain. Evidence of mild rejection as manifested by the appearance of scattered lymphocytes within the graft coincided with the development of Class I and II immunoreactivity within the graft and at the graft-host interface, which was demonstrated in some animals as early as 24 days. At 29 days of age, rejecting grafts showed diffuse MHC expression within the graft and at the graft-host interface; in contrast, unrejected grafts failed to show MHC immunoreactivity. Thirty-four day-old grafts often showed severe rejection with perivascular lymphocytic cuffing within the graft and in host parenchyma remote from the graft associated with increased MHC immunoreactivity within the host brain. In grafts older than 34 days there was frequently a violent rejection reaction with disruption of the cytoarchitecture of the graft and surrounding host tissues, and widespread MHC antigen expression. Immunosuppression with cyclosporin A was effective in avoiding rejection. The high incidence of rejection with neocortical xenografts is in striking contrast to the much lower incidence seen with retinal xenografts. This suggests that there are immunological features unique to neocortex which incite host recognition and rejection.

Evidence that the lamina cribrosa prevents intraretinal myelination of retinal ganglion cell axons

In the majority of mammals axons of retinal ganglion cells are not normally myelinated intraretinally. To test the hypothesis that the lamina cribrosa normally prevents myelin-forming cells from entering the retina we have examined the axons of retinal ganglion cells in conditions where there is no lamina cribrosa. Following transplantation of fetal retinae to the midbrain of newborn rats we have shown that ganglion cell axons within the transplants subsequently become myelinated, providing further evidence that the intraretinal segment of a ganglion cell axon is not refractory to myelination if myelin-forming cells are allowed access. Thus, our results support the hypothesis that the lamina cribrosa normally prevents oligodendrocytes or their precursors from gaining access to the retina. A number of factors may be involved in restricting the migration and differentiation of myelin-forming cells but it is apparent that there is a correlation between the absence or paucity of myelination and the presence of locally increased permeability of the blood-brain barrier. We suggest that proteins derived from plasma may influence oligodendrocyte precursor migration and/or differentiation at these sites.

Neuronal markers in rat retinal grafts

Rat E15 retina was grafted to the retina of adult rat hosts. After varying survival times (1 week-6 months), grafts were stained by immunohistochemistry for neurofilament 160 kDa (NF), HPC-1 (an amacrine cell marker), choline acetyltransferase (ChAT), tyrosine hydroxylase (TH), glutamic acid decarboxylase (GAD) and somatostatin-28 (SS-28). The first differentiating graft amacrine cells (cholinergic and dopaminergic) could be seen 1 week after transplantation (corresponding to postnatal day 1 = P1). The inner plexiform layer of the graft started to differentiate at 2 weeks (corresponding to P8) seen by HPC-1 and GAD staining. ChAT, TH and SS-28 immunostaining revealed an abnormal lamination pattern in the graft inner plexiform layer. Also by 2 weeks, the outer plexiform layers of the graft contained NF-immunoreactive horizontal cells. No NF-stained retinal ganglion cells could be observed in the graft. Five and 7 weeks after grafting, the transplants had obtained the same staining intensity with different markers as the host retina.

Cytochrome oxidase activity in retinas transplanted to the brainstem in rats

Fetal retinas were transplanted to the brainstem of newborn rats and their morphological features were examined using the cytochrome oxidase histochemical method at maturity. The results showed that the inner segments of photoreceptors, outer and inner plexiform layers as well as ganglion cells with large somata were moderately to darkly stained for cytochrome oxidase. This pattern is basically the same as that observed in the normal retina, suggesting that cytochrome oxidase can be used not only for revealing spatial but also functional organization of retinal transplants.

Cotransplantation of embryonic mouse retina with tectum, diencephalon, or cortex to neonatal rat cortex

Retinae from embryonic mice were transplanted to the occipital cortex of neonatal rats together with their normal target regions, tectum or diencephalon, from embryonic mice or rats. In control experiments, retinae were cotransplanted with embryonic rat occipital cortex. In over 80% of the experimental animals, both transplants differentiated and grew. Ganglion cells in the retinae cotransplanted close to tectum or diencephalon survived for at least 15 weeks. Their survival was associated with the development of a distinct optic fiber layer and outgrowth of axons from the transplanted mouse retina. Specific innervation of distinct patches within the cotransplanted rat tectum or diencephalon was demonstrated by the use of an anti-mouse antibody. The innervated regions, which could be as far away as 1.3 mm from the retinae, were correlated with cytological features of the cotransplanted tectum or diencephalon. By contrast, the host cortex was never innervated by the transplanted retinae. In the control animals in which the retinae were cotransplanted with occipital cortex and in four animals in which the cotransplants lay more than 2.7 mm apart, no ganglion cells were identified and there was no evidence of an optic fiber layer, outgrowth of axons, or innervation. These results support the idea that in order to survive, retinal ganglion cells need to innervate an appropriate target region. Further, the specific innervation of regions within the cotransplanted tectum or diencephalon suggests that these target regions are able to exert a tropic influence on the axons of retinal ganglion cells, even in the absence of many of the normal structure cues.

Retinal transplants and optic nerve bridges: possible strategies for visual recovery as a result of trauma or disease

From the review of the current literature it is quite evident that some exciting prospects are on the horizon which will help to better explain the development and functioning of the visual system. In addition, the new technology of CNS tissue grafting coupled to other newly emerging technologies (i.e., microsurgical, microinjection, and micromanipulative techniques coupled with our knowledge of immunosuppressive methods) will allow for a realistic approach in exploring possible strategies for visual recovery as a result of trauma or disease within the near future. One specific area of research that hopefully will emerge from this new body of knowledge comes from the realization that at the present time there is no effective therapy for practically all types of hereditary retinal degenerative disorders in man. It would seem most appropriate to take advantage of the new neuronal transplantation technology mentioned in this article and the availability of hereditary retinal degeneration models in the hope of developing new methods for a therapeutic approach to this problem. Such an approach could involve replacing the abnormal, absent, and/or lost host retinal cells with tissue from healthy donors by means of a grafting technique with the goal of arresting and/or reversing the disease process. Of course, this is but one example of the many challenges in this area of research which increasingly appear to be within our grasp.

Optimum conditions for successful transplantation of immature rat retina to the lesioned adult retina

We have previously reported the successful transplantation of neonatal rat retina to the lesioned retinas of adult host rats. The current studies provide a much more in-depth evaluation of the optimal conditions under which successful grafting can be achieved. Utilizing the same surgical approach and techniques as in our earlier studies, the variables of host lesion conditioning and donor age were investigated. The grafts were evaluated for survival, location, and degree of achievement of selected histological characteristics. The latter category was organized into an evaluation index (E.I.) which provided a consistent system of scoring for purposes of inter-group comparisons. In order to study the effects of lesion conditioning, neonatal grafts were delivered into fresh (0), 1, 2, 4, and 8 week conditioned lesions. Excellent survival and placement were observed at all conditioning times examined. Even the E.I. failed to reveal any statistically significant differences among the lesion conditioning groups. However, there was the suggestion of reduced scarring in the older, more stable lesion groups. The second portion of the study, dealing with donor age, involved the transplantation of E14, E16, E20, PN1, and PN10 retina into freshly lesioned sites in the host retina. Again the result was excellent overall graft survival and placement in all groups. The E.I. score, however, revealed highly significant differences between PN10 grafts and those from all other groups tested. These differences were revealed for all histological criteria with the exception of non-neuronal barrier formation. These studies show the utility of the current model for the repair of retinal lesions over an extended post-traumatic period as well as revealing the wide developmental window for harvesting retinal tissue for the purpose of intravitreal transplantation.

Role of the target in directing the outgrowth of retinal axons: transplants reveal surface-related and surface-independent cues

In the present investigation we have examined whether retinal axons can be directed to the superior colliculus via an alternate route when they do not have access to their normal substrates along the optic tract. To address this issue we transplanted embryonic mouse retinae into the midbrain parenchyma and to various positions around the outer surface of the midbrain of newborn rats and then examined the development of projections from the transplanted tissue. The projections from cortical grafts placed in the midbrain were studied to determine whether axons from different classes of neurons respond to the same cues for outgrowth. When retinae were placed within the midbrain close to the cerebral aqueduct, axons projected dorsally to the superficial layers of the superior colliculus. Directed outgrowth was seen from the earliest time a projection could be detected and was independent of whether the superior colliculus still received host optic afferents. In contrast, the major projection from similarly placed cortical transplants was directed toward the ventral part of the midbrain. Deafferentation of midbrain corticorecipient areas did not affect the projection patterns from either type of graft. Projections from retinae placed more ventrally in the midbrain tegmentum could not be detected. However, retinae placed on the surface of the midbrain, even as far ventral as the cerebral peduncle at the level of the inferior colliculus, always had a projection to the superior colliculus that ran along the brainstem surface. These observations suggest that the superior colliculus exerts a positive influence on the growth of optic axons to the midbrain. However, while target cues appear to be able to support retinal axon growth through the midbrain parenchyma, their range appears to be limited, and at distances beyond the extent of their influence, optic fiber outgrowth occurs only over the surface of the brain. It is suggested, therefore, that there are both local surface-related and target-derived surface-independent cues that guide optic axons to the tectum in developing mammals.

Retinal transplants into the anterior chamber of the rat eye

Developing retinas from 13-18-day fetuses and 2-day neonatal Long-Evans rats transplanted into the anterior chamber of adult eyes of the same or different strain (Lewis) survive and differentiate. Light and electron microscopic studies show that the transplants undergo histogenetic differentiation, resulting in the development of neurons and Müller glial cells and formation of nuclear and plexiform layers. Vascular connections develop between the host iris and the retinal transplant. Vessels and nerves, presumably of iridal origin, were seen on the surface of some transplants. Possible manifestations of graft rejection were monitored; signs of tissue rejection in transplants performed in the Long-Evans rats, an outbred strain, were rare and if present they were mild, at least during the survival periods of up to 91 days allowed in these experiments. Transplants into the eyes of Lewis rats were also well tolerated during the survival period. These observations indicate that retinal transplantation to the adult eye of a genetically different host can be successfully achieved and that both embryonic and perinatal retinas are suitable as donor tissue for ocular transplants. The procedure offers ample opportunities for the study of problems related to retinal plasticity.

The avian pecten provides a potent substrate for growth and development of dissociated embryonic neural implants

A cell suspension of the optic tecta of 3-day-old chick embryos was injected into the vitreal chamber of 2-day-old posthatch chicks. After a 14-21-day survival period, examination of eyeballs showed that all implants survived and, in 50% of cases, were attached to the pecten. The implants had proliferated and showed a laminated pattern of organization, with small cells in the superficial regions and large cells in the deep regions of the implant. The implants also contained a well-developed neuropil with mature synapses. The host retina was not affected by the presence of the implant. We suggest that the avian pecten represents a highly amenable structure for studies involving the response(s) by damaged retinae to neural implants.

Role of target tissue in regulating the development of retinal ganglion cells in the albino rat: effects of kainate lesions in the superior colliculus

Kainic acid or ibotenic acid was injected unilaterally into the major target regions of the axons of retinal ganglion cells--the superior colliculus (SC) or dorsal lateral geniculate nucleus (DLG)--of rat pups ranging in age from postnatal day 0 to postnatal day 10 (P0 - P10). While the collicular or geniculate neurons within the injection site died within 48 hours of the injection, damage to axons and terminals of extrinsic origin within the injected region was not apparent. The neuronal degeneration induced by the neurotoxins, observed at both the light and electron microscopic levels, resembled the neuronal degeneration that occurs in the colliculus during normal development. Macrophages were identified in the regions containing degenerating cells. Two to three weeks after the injections of neurotoxin, massive injections of the enzyme, horseradish peroxidase (HRP), were made into the retinorecipient nuclei. After about 24-hour survival time the numbers of retinal ganglion cells were estimated by counting the number of neurons containing HRP reaction products in sample areas distributed in a regular rectangular array across the entire retinal surface. In the animals in which the neurotoxin was injected into the SC during the first 4 postnatal days, there was a substantial reduction (on average 41.5%; the range: 27.5-65.5%) in the normal number (mean value of 113,000--Potts et al.: Dev. Brain Res. 3:481-486, '82) of retinal ganglion cells surviving the period of "naturally occurring ganglion cell death" in the retinae contralateral to the injected SC. By contrast, injections of neurotoxins into the DLG and/or the optic tract of newborn rats did not result in a significant reduction in the numbers of retinal ganglion cells surviving the period of naturally occurring ganglion cell death. The period of sensitivity of retinal ganglion cells to the injection of neurotoxin into the colliculi extends from birth to about the end of the first postnatal week; the greatest sensitivity seems to be restricted to the first 3-4 postnatal days. In the retinae in which the total number (and density) of ganglion cells was substantially reduced by the selective destruction of their target cells, the centro-peripheral difference in the somal diameters of the ganglion cells (apparent in normal animals) was abolished, both amongst the whole population of ganglion cells and amongst the ganglion cells with the largest somata, relatively thick axons, and large-gauge primary dendrites (Class I cells). The number and distribution of the Class I cells in the depleted retinae were, however, unaltered.(ABSTRACT TRUNCATED AT 400 WORDS)

Newborn rat retinal cells transplanted into a retinal lesion site in adult host eyes

We report the successful grafting of embryonic (newborn) rat retina into a lesion site (die-back zone) of an adult retina with a corresponding 90-100% survival rate. A penetrating lesion was made through the sclera, choroid and retina on the superior surface of the host eye and closed with microsutures. The lesion site was either allowed to stabilize for 5 weeks or immediately received a retinal graft. Retinas were removed from 1-day-old neonate donors, drawn through a small gauge needle and injected into the fresh or stabilized lesion site. Host animals were sacrificed and the eyes processed for light, scanning- and transmission-electron microscopic analysis at 1, 2, and 4 weeks after grafting. Analysis of sections through grafted tissue within the lesion site revealed that the neonatal cells not only survived at all times examined but also continued their development reminiscent of normal littermate controls. Examination of 4-week grafts revealed a laminar pattern similar to adult ganglion cell, inner plexiform, inner nuclear, and outer plexiform layers as well as developing photoreceptor neurons. The grafted tissue could easily be delivered into the retinal lesion site where it established a pattern of retinal layers within the die-back zone. In addition, the plexiform areas of the graft appeared to integrate with those of the host. The age of the adult retina lesion transplantation site had little effect on the graft/host integrative phenomenon. These studies show for the first time a method utilizing immature retinal grafts to fill and/or bridge the wound area of the lesioned adult mammalian retina. These observations also demonstrate the utility of using this model for the study of numerous retinal developmental phenomena.

The morphology of neurons in rat tectal transplants as revealed by Golgi-Cox impregnation

The Golgi technique has been used to examine the morphology of neurons within tectal transplants. Embryonic tectal tissue was transplanted to the midbrain of newborn rats. Four to eight months later, host animals were decapitated under anaesthesia, the unfixed brains removed and processed by Golgi-Cox impregnation. In tectal grafts, different types of neuron were recognized on the basis of the size and shape of their somata and the morphology of their dendritic trees. Neuronal types found in transplants resembled cell classes found in normal rat superior colliculus (SC). Neurons characteristic of the superficial collicular layers such as marginal, ganglion type I, stellate and horizontal cells and multipolar cells typical of the deeper collicular layers were identified in the transplants. Compared with normal cells, grafted neurons often had smaller dendritic fields and fewer dendritic spines. No laminar organization was discernable in the grafts and there was commonly no preferential orientation of perikarya or dendrites. Small cells with similar dendritic morphology were sometimes found grouped together in patches within the graft neuropil. These patches resembled cytologically and histochemically distinct areas described in previous studies and may represent areas homologous to the superficial layers of normal SC.

Use of a species-specific antibody for demonstrating mouse neurons transplanted to rat brains

A cell surface monoclonal antibody specific for mouse central nervous system neurons was used to identify mouse tissue transplanted to neonatal rat brains. Neuronal cell bodies and processes were stained in the transplants. Immature axons were stained growing out of the transplants into the host brain; and in mature brains unmyelinated axons and terminal plexuses were demonstrated. The technique allows a variety of studies to be performed on transplant-host interactions, especially in circumstances where the two are closely apposed.