Embryonic retinal ablation and post-metamorphic optic nerve crush: effects upon the pattern of regenerated retinotectal connections.

We examined relationships between healing observed during embryonic Xenopus retinal and optic nerve regeneration and resultant visuotectal pattern formation. Dorsal (D) and nasoventral (NV) 1/3 sized eye fragments were surgically created in stage 32 Xenopus laevis embryos. Gross anatomical healing modes of these fragments were examined 2 days post-surgery (stage 43). Healing was categorized according to the degree of cell movements observed. Animals were reared through metamorphosis and electrophysiologic mapping techniques were employed on those animals whose eyes regenerated. All D 1/3 fragments showed normal (non-duplicated) projections to the tectum; most (80%) of the healing observed showed little cell movements (the remaining 20% showed substantial cell movements, yet failed to show duplicated projections). Most NV 1/3 fragments (73%) formed two mirror image projections to the contralateral midbrain optic tectum (pattern duplication). Most (88%) of the healing observed among these animals showed massive cell movements in the ventral retinal region (the remaining 12% showed moderate cell movements). The remaining NV 1/3 fragments (27%) showed moderate cell displacement and failed to show duplicated projections). These data are compatible with a cell-movement:intercalary cell division hypothesis in which duplication is dependent upon specific positional confrontation and subsequent cell division. In additional studies, in adult animals, the optic nerves of eyes with duplicated projections were crushed and allowed to regenerate for 1 year. Duplicated projections were restored, indicating that developmental and maturational factors are probably not responsible for duplicative pattern formation; rather, information intrinsic to the eye, possibly created during healing interactions and/or fiber ingrowth to the tectum, underlies duplicate innervation of the tectum.     

An autoradiographic time study during regeneration in fully differentiated Xenopus eyes.

Nasal one-third sized fragments were created from fully differentiated larval Xenopus eyes (stage 47). At various times post-surgery, animals were injected with tritiated thymidine. All animals were fixed 1 day post-injection. Animals injected 1 day post-surgery showed limited healing and thymidine labeling in the retina. In animals injected 1 week post-surgery, heavy thymidine label was localized in the ventrotemporal retina in a "thickened" neuroepithelium internal to the extending pigmented retinal epithelium. In contrast, the dorsal retina showed no apparent extra labeling, but rather resembled normal ciliary margin. In animals injected 1 month post-surgery, the eye fragment regained normal size and retinal layering, and the label was restricted to the ciliary margin. Regenerative growth associated with healing appeared to have been completed by this time. This extra cell division that occurs during the 1st month post-surgery may underlie novel axonal targeting properties shown by nasal one-third sized fragments. For example, these findings are consistent with the idea that pattern duplication of the visuotectal projection in nasal one-third sized eye fragments occurs via intercalary cell division during healing and regeneration.     

Development of neuronal locus specificity in Xenopus retinal ganglion cells after surgical eye transection after fusion of whole eyes

A developmental program is established in the stage 28–32 optic cup of Xenopus embryos, which specifies the permanent AP and DV reference axes for positional information in the retina, and thereby determines the pattern of spatial deployment of ganglion cell locus specificities subserving assembly of retinotopically organized connections in the tectum. This developmental program has previously proved unmodifiable in intact eye primordia submitted to a variety of rotation, transplantation, and tissue culture conditions. Here we report that the program can be modified by surgical transection of stage 32 eye primordia (with subsequent fusion of the disconnected halves to reconstitute a whole eye) and by fusion of whole stage 38 eyes, although most of the transected eyes did develop normal visuotectal projections. The remaining vertically transected eyes, and all eyes formed when a left and right stage 38 eye fused along apposed temporal edges, developed “double-nasal compound” projections to the tectum: the nasal and temporal halves of the adult retina each projected to the entire tectum, and each tectal locus was driven from two stimulus positions symmetrically disposed about the vertical meridian. The remaining horizontally transected eyes, and all eyes formed when a left and right stage 38 eye fused along apposed dorsal edges, developed “double-ventral compound” projections to the tectum: the dorsal and ventral halves of the adult retina each projected to the entire tectum, and each tectal locus was driven from two stimulus positions symmetrically disposed about the horizontal meridian. The results are considered in terms of (1) the kinds of cellular processes that could mediate the observed modifications in the original developmental program; (2) the nature and stability of the program; and (3) the general suitability of eye fragment-fusion experiments for analysis of the assembly of retinotectal connections.     

Continued growth and circuit building in the anamniote visual system

Fish and amphibia are capable of lifelong growth and regeneration. The two core components of their visual system, the retina and tectum both maintain small populations of stem cells that contribute new neurons and glia to these tissues as they grow. As the animals age, the initial retinal projections onto the tectum are continuously remodeled to maintain retinotopy. These properties raise several biological challenges related to the control of proliferation and differentiation of retinal and tectal stem cells. For instance, how do stem and progenitor cells integrate intrinsic and extrinsic cues to produce the appropriate type and number of cells needed by the growing tissue. Does retinal growth or neuronal activity influence tectal growth? What are the cellular and molecular mechanisms that enable retinal axons to shift their tectal connections as these two tissues grow in incongruent patterns? While we cannot yet provide answers to these questions, this review attempts to supply background and context, laying the ground work for new investigations.     

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.     

Ontogenetic development of S-antigen- and rodopsin immunoreactions in retinal and pineal photoreceptors of Xenopus laevis in relation to the onset of melatonin-dependent color-change mechanisms

Summary In Xenopus laevis Daud., the ontogenetic occurrence of two photoreceptor-specific proteins, S-antigen and rod-opsin, was investigated and correlated to the maturation of the neurohormonal effector system involved in melatonin-dependent color-change mechanisms. Tadpoles ranging from stage 12 to 57 (Nieuwkoop and Faber 1956) were fixed in Zamboni's or Bouin's solution. Frozen or paraffin sections of either total heads or dissected brains and eyes were prepared and treated with highly specific antisera against S-antigen and rod-opsin. In the retina, immunoreactive S-antigen and rod-opsin were first demonstrated in a few centrally located photoreceptors at stage 37/38. Photoreceptors of the peripheral (iridical) portions of the retina gradually became immunoreactive during further development. As in the retina, the first S-antigen-immunoreactive photoreceptors in the pineal complex appeared at stage 37/ 38. At this and all later stages investigated rod-opsin immunoreactivity was restricted to a few dot-like structures resembling developing pineal outer and inner segments. In most animals rod-opsin immunoreactivity was completely absent from the pineal complex. The analysis of retinal proteins with the immunoblotting technique (Western blot) revealed that the S-antigen antibody bound to a 48-kDa protein and the rod-opsin antibody to a 38-kDa protein. The body lightening reaction was determined with the aid of the melanophore index in larvae fixed in light or darkness, respectively. Aggregation of melanophore melanosomes in darkness (the melatonin-dependent primary chromatic response) first occurred at stage 37/38 when melanophores started to differentiate and became pigmented. These results indicate that in Xenopus laevis (i) the molecular mechanisms of photoreception develop simultaneously in retina and pineal complex; (ii) most pineal photoreceptors differ from retinal rods in that they contain immunoreactive S-antigen but essentially no immunoreactive rod-opsin; and (iii) the differentiation of phototransduction processes coincides with the onset of melatonin-dependent photoneuroendocrine regulation of color-change mechanisms.Supported by USUHS protocol C07049 (MDR) and the Deutsche Forschungsgemeinschaft (HWK)     

Healing modes correlate with visuotectal pattern formation in regenerating embryonic Xenopus retina

After removal of the nasal or the temporal two-thirds of the embryonic (stage 32) eye, the remaining one-third sized fragment undergoes wound healing and then, in most cases, regenerates to form a new eye. Using gross anatomy and histology techniques, we categorized eye fragments into three healing mode categories over the first 24 hr after surgery (stage 37-38). Representative animals were reared through metamorphosis and their visuotectal projections were assayed using standard electrophysiology techniques. In the "rounded-up" healing mode, the cut edges of the fragment pinch to close the wound; retinal cell type layers (pigmented retinal epithelium (pre), photoreceptors, interneurons, ganglion cells) and a lens are present by 24 hr postsurgery. No extraneous or disorganized cells are present either internal or external to the fragments. These fragments regenerated to form normal projections 83% of the time and pattern duplicated projections only 17% of the time. In the "intermediate" healing mode, wound closure is not complete by 24 hr post surgery and groups of disorganized cells are present in the fragment and amassed between the healing cut edges. These fragments formed pattern duplicated projections 72% of the time. In the tongue healing mode, an ectopic mass of cells, contiguous with the main body of the fragment, forms a supernumerary retina in the region of the ablation. At 24 hr post surgery, the cells of the main body fragment form retinal layers; the cells of the tongue, excluding the presence of differentiated pre cells, remain undifferentiated, resembling ciliary margin. The cut edges of the main body fragment eventually fuse with the tongue to form a single eyeball. Tongue fragments formed pattern duplicated projections 100% of the time. In addition, pattern duplicated points derived from nasal fragments appeared most often in the posterior region of the tectum, the normal site of innervation of the nasal retina. This differed significantly from temporal fragment derived duplicated points which appeared more often in the front of the tectum, the normal site of innervation by temporal retina. Thus, the specificity of pattern duplicated innervation is related to the positional values remaining in the fragment after partial retinal ablation. The data indicate that cell movements during healing, whether overt as in the tongue healing mode, or remaining internal to the fragment as in the intermediate healing mode, are intimately correlated with pattern forming mechanisms which underlie pathological visuotectal duplication.     

Specificity and retinotectal projections of quarter-eye fragments in Xenopus laevis

Three quarters of the eye anlage in Xenopus embryos of stage 33/34 were eliminated in three different sets of experiments. The remaining quadrant originated from the nasoventral part of the retina, from its ventral portion, or from the temporo-ventral area of the retina. All the fragments developed into small eyes of normal shape. The retinotectal connections did not deviate from those found in the control groups, even though mirror-image duplication was fairly frequent. For all fragments the tectal projection fields were rather limited. There was some indication of fragments retaining their original specificity. Irrespective, however, of their different origins, the optic projections always occupied the rostrolateral area of the tectum.     

Upregulation of matrix metalloproteinase triggers transdifferentiation of retinal pigmented epithelial cells in Xenopus laevis: A Link between inflammatory response and regeneration

In adult Xenopus eyes, when the whole retina is removed, retinal pigmented epithelial (RPE) cells become activated to be retinal stem cells and regenerate the whole retina. In the present study, using a tissue culture model, it was examined whether upregulation of matrix metalloproteinases (Mmps) triggers retinal regeneration. Soon after retinal removal, Xmmp9 and Xmmp18 were strongly upregulated in the tissues of the RPE and the choroid. In the culture, Mmp expression in the RPE cells corresponded with their migration from the choroid. A potent MMP inhibitor, 1,10‐PNTL, suppressed RPE cell migration, proliferation, and formation of an epithelial structure in vitro. The mechanism involved in upregulation of Mmps was further investigated. After retinal removal, inflammatory cytokine genes, IL‐1β and TNF‐α , were upregulated both in vivo and in vitro. When the inflammation inhibitors dexamethasone or Withaferin A were applied in vitro, RPE cell migration was severely affected, suppressing transdifferentiation. These results demonstrate that Mmps play a pivotal role in retinal regeneration, and suggest that inflammatory cytokines trigger Mmp upregulation, indicating a direct link between the inflammatory reaction and retinal regeneration. © 2017 Wiley Periodicals, Inc. Develop Neurobiol 77: 1086–1100, 2017     

Ocular dominance stripe formation by regenerated isogenic double temporal retina in Xenopus laevis

In lower vertebrates such as frogs and fish, long ocular dominance stripes with anterior-posterior (A-P) orientation can be produced by causing both eyes to innervate one optic tectum during the course of development. Similar experiments on adult animals usually produce patches rather than stripes. During development, new retinal fibers from the nasal retina segregate into appropriate stripes at the growing edge of the posterior (P) tectum while new temporal fibers segregate at the non-growing anterior (A) tectal edge. Fiber segregation into long A-P oriented stripes might depend upon a template produced by new nasal fibers initiating stripe orientation in the vicinity of new tectal cells; new nasal fibers would orient to the nascent (posterior) edge of the template while temporal fibers would orient to the anterior (non-growing) end of the template. To test the dependence of stripe formation on the matching of nascent retinal cells with nascent tectal cells, we compared stripe orientation in animals with isogenic double nasal innervation and isogenic double temporal innervation of the tectum. In double nasal innervation, the oldest retinal cells innervate the anterior tectum; new fibers from the entire retinal periphery always innervate the newest tectal cells at the posterior tectum. Stripes are oriented A-P, consistent with a maturation front model. In contrast, the oldest retinal cells innervate the newest (posterior) tectal cells in double temporal innervation of the tectum; the growing retinal periphery innervates the non-growing anterior tectum. Stripes are also oriented A-P, indicating that the production of long stripes does not depend upon maturation front matching of nascent retinal fibers and nascent tectal cells.     

Neural retinal regeneration in the anuran amphibian Xenopus laevis post-metamorphosis: transdifferentiation of retinal pigmented epithelium regenerates the neural retina

In urodele amphibians like the newt, complete retina and lens regeneration occurs throughout their lives. In contrast, anuran amphibians retain this capacity only in the larval stage and quickly lose it during metamorphosis. It is believed that they are unable to regenerate these tissues after metamorphosis. However, contrary to this generally accepted notion, here we report that both the neural retina (NR) and lens regenerate following the surgical removal of these tissues in the anuran amphibian, Xenopus laevis, even in the mature animal. The NR regenerated both from the retinal pigment epithelial (RPE) cells by transdifferentiation and from the stem cells in the ciliary marginal zone (CMZ) by differentiation. In the early stage of NR regeneration (5-10 days post operation), RPE cells appeared to delaminate from the RPE layer and adhere to the remaining retinal vascular membrane. Thereafter, they underwent transdifferentiation to regenerate the NR layer. An in vitro culture study also revealed that RPE cells differentiated into neurons and that this was accelerated by the presence of FGF-2 and IGF-1. The source of the regenerating lens appeared to be remaining lens epithelium, suggesting that this is a kind of repair process rather than regeneration. Thus, we show for the first time that anuran amphibians retain the capacity for retinal regeneration after metamorphosis, similarly to urodeles, but that the mode of regeneration differs between the two orders. Our study provides a new tool for the molecular analysis of regulatory mechanisms involved in retinal and lens regeneration by providing an alternative animal model to the newt, the only other experimental model.     

Induction of retinal regeneration in vivo by growth factors

We have previously reported that basic fibroblast growth factor (bFGF) can induce retinal regeneration in the stage 22-24 chicken embryo. The present study was undertaken to identify the cellular source of the regenerate and to determine whether other growth factors also elicit regeneration in this animal model. Polymer implants containing bFGF were inserted into eyes of chicken embryos immediately after extirpation of the neural retina. The retinal pigment epithelium (RPE) was left intact. Evaluation by light microscopy revealed that in bFGF-treated eyes the new neural retina arose by transdifferentiation of the entire RPE layer. Differentiation of the new neural retina occurred in a sequence similar to that of normal development but proceeded in a reverse (vitread) direction. All retinal laminae had differentiated by Day 15. However, the regenerate displayed reversed polarity, with photoreceptors closest to the lens. The RPE, pecten, and optic nerve were absent. Focal areas of degeneration in the retinal regenerate became evident for the first time on Day 10. Retinal regeneration was also observed after treatment with higher doses of acidic fibroblast growth factor, but not with nerve growth factor-beta, transforming growth factor-beta 1, insulin, or insulin-like growth factors I or II. These results raise the possibility that FGFs may play a role in retinal differentiation during development.     

Retinal stem/progenitor cells in the ciliary marginal zone complete retinal regeneration: A study of retinal regeneration in a novel animal model

Our research group has extensively studied retinal regeneration in adult Xenopus laevis. However, X. laevis does not represent a suitable model for multigenerational genetics and genomic approaches. Instead, Xenopus tropicalis is considered as the ideal model for these studies, although little is known about retinal regeneration in X. tropicalis. In the present study, we showed that a complete retina regenerates at approximately 30 days after whole retinal removal. The regenerating retina was derived from the stem/progenitor cells in the ciliary marginal zone (CMZ), indicating a novel mode of vertebrate retinal regeneration, which has not been previously reported. In a previous study, we showed that in X. laevis, retinal regeneration occurs primarily through the transdifferentiation of retinal pigmented epithelial (RPE) cells. RPE cells migrate to the retinal vascular membrane and reform a new epithelium, which then differentiates into the retina. In X. tropicalis, RPE cells also migrated to the vascular membrane, but transdifferentiation was not evident. Using two tissue culture models of RPE tissues, it was shown that in X. laevis RPE culture neuronal differentiation and reconstruction of the retinal three‐dimensional (3‐D) structure were clearly observed, while in X. tropicalis RPE culture neither ßIII tubulin‐positive cells nor 3‐D retinal structure were seen. These results indicate that the two Xenopus species are excellent models to clarify the cellular and molecular mechanisms of retinal regeneration, as these animals have contrasting modes of regeneration; one mode primarily involves RPE cells and the other mode involves stem/progenitor cells in the CMZ. © 2014 Wiley Periodicals, Inc. Develop Neurobiol 74: 739–756, 2014     

Regeneration of the amphibian retina: role of tissue interaction and related signaling molecules on RPE transdifferentiation

Regeneration of eye tissue is one of the classic subjects in developmental biology and it is now being vigorously studied to reveal the cellular and molecular mechanisms involved. Although many experimental animal models have been studied, there may be a common basic mechanism that governs retinal regeneration. This can also control ocular development, suggesting the existence of a common principle between the development and regeneration of eye tissues. This notion is now becoming more widely accepted by recent studies on the genetic regulation of ocular development. Retinal regeneration can take place in a variety of vertebrates including fish, amphibians and birds. The newt, however, has been considered to be the sole animal that can regenerate the whole retina after the complete removal of the retina. We recently discovered that the anuran amphibian also retains a similar ability in the mature stage, suggesting the possibility that such a potential could be found in other animal species. In the present review article, retinal regeneration of amphibians (the newt and Xenopus laevis) and avian embryos are described, with a particular focus on transdifferentiation of retinal pigmented epithelium. One of the recent progresses in this field is the availability of tissue culture methods to analyze the initial process of transdifferentiation, and this enables us to compare the proliferation and neural differentiation of retinal pigmented epithelial cells from various animal species under the same conditions. It was revealed that tissue interactions between the retinal pigmented epithelium and underlying connective tissues (the choroid) play a substantial role in transdifferentiation and that this is mediated by a diffusible signal such as fibroblast growth factor 2. We propose that tissue interaction, particularly mesenchyme-neuroepithelial interaction, is considered to play a fundamental role both in retinal development and regeneration.     

Model for the retino-tectal projection

A model for the retino-tectal projection is proposed which assumes that axonal growth proceeds predominantly in the direction of maximal slope of a guiding substance (or, more generally, of a system parameter subsuming the effect of several substances). The spatial distribution of this parameter, in turn, results from the interaction of components of retinal axons (which are graded with respect to position of origin in the retina) and tectal components. One or two gradients in each dimension of retina and tectum suffice. Conditions for the generation of a reliable projection on this basis are relatively simple and consistent with conventional enzyme and receptor kinetics. Adhesive forces could but need not be involved in the guiding mechanism. The slope of guiding substances that interfere with an intracellular pattern-forming mechanism within the growth cone may determine the polarity of activation and thus the direction of growth. Generation of primary projections and some features of regulation such as independence of projections on neural pathways, and observations on the innervation of rotated pieces of tectum, can be explained on the basis of the model. The model can be extended by introducing additional production of guiding substance depending on the density, and duration of presence, of fibre terminals in the course of innervation. This simple mechanism would suffice for observed effects of compression and expansion of the map following ablation of retinal and tectal tissue, respectively. It may but need not be involved in the primary projection, too.     

Transgenic Xenopus laevis with the ef1-α promoter as an experimental tool for amphibian retinal regeneration study

Complete retinal regeneration occurs after the removal of the whole tissue in mature Xenopus laevis, as well as in the newt. Here, we produced F1 and F2 lines of transgenic X. laevis containing an EGFP gene under a translation elongation factor 1‐α (ef1‐α) promoter and investigated how the gene is reactivated in retinal pigmented epithelial (RPE) cells when the neural retina (NR) is removed. The results showed that EGFP expression is reduced in the adult ocular tissues of nonmanipulated transgenic animals, and EGFP‐expressing cells are occasionally found heterogeneously in the lens, NR and RPE tissues. During retinal regeneration, the EGFP gene is reactivated in the RPE and ciliary marginal cells. Transgenic animals were also used for a transplant study because of the genetic marker of the donor tissue. Transplanted RPE clearly transdifferentiated to regenerate the retina in the ocular chamber. This study is, to our knowledge, the first report of a transgenic study of amphibian retinal regeneration, and the approach is promising for future molecular analyses. genesis 50:642–650, 2012. © 2012 Wiley Periodicals, Inc.     

Competitive interactions between retinal ganglion axons for tectal targets explain plasticity of retinotectal projection in the servomechanism model of retinotectal mapping

The mechanism of topographic mapping of retinal ganglion cells to the midbrain was previously elucidated by the servomechanism model, which is based on the fact that cells expressing Eph-receptors respond specifically to surface expressing membrane-bound ephrin-ligands at a critical level. The retina has increased nasal-to-temporal gradient of Eph receptor-density, and the optic tectum/superior colliculus has increased rostral-to-caudal gradient of membrane-bound ephrin-ligand. An axon from the retina has an identification tag of a certain level of Eph-receptor density depending on its retinal position, and adheres to the site on the tectum/superior colliculus expressing ephrin-ligands at a critical ligand-density level. The servomechanism model rigidly defines positions of axon terminals on the midbrain. However, optic nerve regeneration experiments combined with halved retina or tectum show a plastic or flexible mapping (expansion, compression and transposition of tectal projections). To reconcile the discrepancy between the rigid model and the plastic behavior, competition between retinal axon terminals for a target site was introduced to the servomechanism. The servomechanism/competition model succeeded in computer simulations of the plastic mapping of retinal axons on the tectum. Recent experiments of upregulated ligand-density on the tectum during nerve regeneration and the role of axonal competition are discussed.     

Pax-6 expression during retinal regeneration in the adult newt

The present study examined the expression of Pax-6 during retinal regeneration in adult newts using in situ hybridization. In a normal retina, Pax-6 is expressed in the ciliary marginal zone, the inner part of the inner nuclear layer, and the ganglion cell layer. After surgical removal of the neural retina, retinal pigment epithelial cells proliferate into retinal precursor cells and regenerate a fully functional retina. At the beginning of retinal regeneration, Pax-6 was expressed in all retinal precursor cells. As regeneration proceeded, differentiating cells appeared at the scleral and vitreal margins of the regenerating retina, which had no distinct plexiform layers. In this stage, the expression of Pax-6 was localized in a strip of cells along the vitreal margin of the regenerating retina. In the late stage of regeneration, when the layer structure was completed, the expression pattern of Pax-6 became similar to that of a normal retina. It was found that Pax-6 is expressed in the retinal precursor cells in the early regenerating retina and that the expression pattern of Pax-6 changed as cell differentiation proceeded during retinal regeneration.     

Cross-species recognition of tectal cues by retinal fibers in vitro

The retinae of vertebrates project in a topographic manner to several visual centers of the brain. The formation of these projections could depend on the existence of position-specific properties of retinal and target cells. In this study, we have tested the in vitro growth of mouse retinal fibers on membranes derived from various regions of the embryonic superior colliculus, a main target of the retina in this species. Fibers had the choice of elongating on membranes taken from either the anterior or the posterior half of the superior colliculus. Fibers from temporal areas of the retina prefer to elongate on anterior collicular membranes, while fibers from nasal areas do not show a preference. These phenomena are observed with membranes from embryonic (E15-E18) or young postnatal mice. In interspecies cultures where mouse retinal fibers had to grow on chick tectal membranes, or vice versa, the same preference for anterior tectal or collicular membranes in growth of temporal retinal fibers is observed, suggesting some similarities in the cues used in both species.