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.     

Fully differentiated Xenopus eye fragments regenerate to form pattern-duplicated visuo-tectal projections

In order to determine if differentiated Xenopus retina is capable of undergoing regeneration and duplicative pattern formation, we devised a new surgical technique for removal of the temporal two-thirds of the retina. In a series of progressively older larval eyes starting with late tailbud stage embryos (stage 38) and extending to limb-bud stage tadpoles (stage 48), nasal one-third-sized eye fragments successfully regenerated to form nearly normal sized eyes over 75% of the time. Histological preparations showed that early wound healing involved the formation of a neuroepithelium at the ventro-temporal region of the fragment. The pigmented retinal epithelium and associated retinal tissue appeared to be involved in this process. Animals from each stage were reared through metamorphosis and electrophysiologic techniques were employed to determine visuo-tectal projections. Seventy percent of stage 38 animals showed evidence of pattern-duplicated projections. Ninety percent of their responding tectal points showed duplicate innervation from two retinal regions. Older animals (stages 44 to 48) showed less duplication. Only 52% of their responding tectal points duplicated (P less than 0.001). Thus, fully differentiated Xenopus retina can undergo regeneration and duplicative pattern formation similar to that shown by embryonic retinal tissue.     

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.     

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.     

Convergence of multisensory inputs in Xenopus tadpole tectum

The integration of multisensory information takes place in the optic tectum where visual and auditory/mechanosensory inputs converge and regulate motor outputs. The circuits that integrate multisensory information are poorly understood. In an effort to identify the basic components of a multisensory integrative circuit, we determined the projections of the mechanosensory input from the periphery to the optic tectum and compared their distribution to the retinotectal inputs in Xenopus laevis tadpoles using dye‐labeling methods. The peripheral ganglia of the lateral line system project to the ipsilateral hindbrain and the axons representing mechanosensory inputs along the anterior/posterior body axis are mapped along the ventrodorsal axis in the axon tract in the dorsal column of the hindbrain. Hindbrain neurons project axons to the contralateral optic tectum. The neurons from anterior and posterior hindbrain regions project axons to the dorsal and ventral tectum, respectively. While the retinotectal axons project to a superficial lamina in the tectal neuropil, the hindbrain axons project to a deep neuropil layer. Calcium imaging showed that multimodal inputs converge on tectal neurons. The layer‐specific projections of the hindbrain and retinal axons suggest a functional segregation of sensory inputs to proximal and distal tectal cell dendrites, respectively. © 2009 Wiley Periodicals, Inc. Develop Neurobiol, 2009     

Ipsilateral retinal projections into the tectum during regeneration of the optic nerve in the cichlid fish Haplochromis burtoni: a Dil study in fixed tissue.

Retinal projections were experimentally manipulated in a bony fish to reveal conditions under which considerably enlarged ipsilateral projections developed and persisted. Three experimental groups were studied: animals after unilateral enucleation, after unilateral nerve crush, and after enucleation and crush of the remaining optic nerve. At 29 days after unilateral enucleation alone, no enhanced ipsilateral projection had developed. After nerve crush, however, large numbers of retinal fibers regenerated into the ipsilateral tectum. Retrogradely filled, ipsilaterally projecting ganglion cells were distributed throughout the entire retina. After 15 days regenerating retinal fibers covered the entire ipsilateral tectum. At later stages the ipsilateral projection showed progressive reduction in coverage of the tectum. Combining enucleation with nerve crush led to an ipsilateral projection that covered the tectum at 28 days and later. In this experimental situation the development of an ipsilateral projection appears to be a two-step process: (1) Fibers are rerouted to the ipsilateral side at the diencephalon, and (2) ipsilateral fibers persist in the tectum only in the absence of a contralateral projection while they appear to be eliminated in the other cases.     

Ipsilateral retinal projections into the tectum during regeneration of the optic nerve in the cichlid fish Haplochromis burtoni: A dil study in fixed tissue

Retinal projections were experimentally manipulated in a bony fish to reveal conditions under which considerably enlarged ipsilateral projections developed and persisted. Three experimental groups were studied: animals after unilateral enucleation, after unilateral nerve crush, and after enucleation and crush of the remaining optic nerve. At 29 days after unilateral enucleation alone, no enhanced ipsilateral projection had developed. After nerve crush, however, large numbers of retinal fibers regenerated into the ipsilateral tectum. Retrogradely filled, ipsilaterally projecting ganglion cells were distributed throughout the entire retina. After 15 days regenerating retinal fibers covered the entire ipsilateral tectum. At later stages the ipsilateral projection showed progressive reduction in coverage of the tectum. Combining enucleation with nerve crush led to an ipsilateral projection that covered the tectum at 28 days and later. In this experimental situation the development of an ipsilateral projection appears to be a two-step process: (1) Fibers are rerouted to the ipsilateral side at the diencephalon, and (2) ipsilateral fibers persist in the tectum only in the absence of a contralateral projection while they appear to be eliminated in the other cases. © 1992 John Wiley & Sons, Inc.     

Control of pattern duplication in the retinotectal system of Xenopus. Suppression of duplication by eye-fragment interactions.

Recombining right nasal half-eyes with left temporal half-eyes at embryonic stage 32 in Xenopus produces a double or “twinned” pattern of functional connections between retina and midbrain optic tectum. The left temporal half-eye is reprogrammed such that it projects to the tectum as a mirror-image duplicate pattern of the nasal right half-eye; both half-eyes project across the entire tectum. However, recombining a right nasal half-eye (in situ) with a right dorsal half-eye (grafted into the temporal position; N_RD_R eye) produces a single normal retinotectal projection. Where interactions between N_R and T_L involve both axial reprogramming and duplication of N_R positional values in T_L, N_RD_R interactions involve axial reprogramming in D_R without duplication of N_R values. In a second approach to interactions which suppress pattern duplication, both nasal and temporal one-third-sized eye fragments form approximate “NN” or “TT” duplicate pattern maps, respectively, when either is allowed to round up and form a whole eye. Allowing nasal and temporal thirds to permanently fuse (after removal of a one-third-sized vertical center strip of retina at stage 32) produces a normal projection; allowing the nasal and temporal thirds to interact (fuse) for 35–40 hr, followed by removal of one or the other third, suppresses pattern duplication (produces normal maps) in the remaining third in a majority of cases. Allowing the thirds to interact for 18–30 hr before removal of the temporal third produces a majority result of partial duplication in the remaining nasal third. Partial duplicates are apparent spatial intermediates with regard to interactions which suppress duplication in either fragment type.     

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.     

Specific cell surface labels in the visual centers of Xenopus laevis tadpole identified using monoclonal antibodies

Monoclonal antibodies (MAbs) against the optic tectum of Xenopus tadpoles were generated and screened by the immunofluorescent staining of frozen sections of tadpole brains. MAb-A5 stains the 8th and 9th plexiform layers of the optic tectum, whereas MAb-B2 stains all but the eighth and ninth plexiform layers of the optic tectum. MAb-A5 antigen is also detectable in the nucleus of Belonci, the corpus geniculatum thalamicum, the pretectal area, and the basal optic nucleus, all targets of the optic nerve, but is not detectable in the optic nerve or the optic tract. On the other hand, MAb-B2 does not stain any of these visual centers, though many fibers surrounding them are stained. Eye-enucleation experiments showed that MAb-A5 antigen is expressed in the optic tectum even when it is not innervated by optic nerves. Staining of viable brains with these MAbs indicates that these antigens are cell surface molecules. Immunoadsorption followed by SDS-PAGE suggests that proteins are constituents of these antigens. The MAb-A5 antigen in the diencephalon and the mesencephalon is not detectable at stage 35/36, but is detectable at stage 39 when the optic nerves begin to innervate the optic tectum. The spatial as well as the temporal patterns of the expression of the MAb-A5 antigen suggest that this molecule may be involved in the target recognition of optic nerve fibers.     

Homotopic and heterotopic transplantations of quail tectal primordia in chick embryos: Organization of the retinotectal projections in the chimeric embryos

To study the adaptative capabilities of the retinotectal system in birds, the primordium of one optic tectum from 12-somite embryos of Japanese quail was transplanted either homotopically, to replace the ablated same primordium, or heterotopically, to replace the ablated dorsal diencephalon in White Leghorn chick embryos of the same stage. The quail nucleolar marker was used to recognize the transplants. The cytoarchitecture of the tecta and the retinal projections from the eye contralateral to the graft were studied on the 17th or 18th day of incubation in the chimeric embryos by autoradiographic or horseradish peroxidase tracing methods. Morphometric analysis was applied to evaluate the percentage of the tectal surface receiving optic projections. It was observed that: (i) quail mesencephalic alar plate can develop a fully laminated optic tectum even when transplanted heterotopically; (ii) retinal ganglion cells from the chick not only recognize the tectal neurons of the quail as their specific targets in homotopic grafts, but the optic fibers deviate to innervate the heterotopically grafted tectum; (iii) in the presence of a graft, the chick retina is unable to innervate a tectal surface of similar or larger size than that of the control tectum; (iv) tectal regions devoid of optic projections, whether formed by donor or by host cells, always present an atrophic lamination; (v) the diencephalic supernumerary optic tectum competes with and prevails over the host tectum as a target for optic fiber terminals.     

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.     

2’-Deoxyadenosine causes cell death in embryonic chicken sympathetic ganglia and brain

Previous work has shown that nucleosides produce apoptosis in sympathetic ganglion (SG) cells in vitro. The present study examined the effects of nucleosides on the development of the chick embryo in vivo with special attention to the SG and the optic tectum of the central nervous system. In the presence of an adenosine deaminase inhibitor, adenosine and 2'-deoxyadenosine (2'-dAdo) produced different toxicity patterns: both adenosine and 2'-dAdo were toxic to E3 embryos, but only 2'-dAdo was toxic at later stages (E6 1/2, E11). Dosage experiments on E6 1/2 embryos showed that adenosine was less toxic than 2'-dAdo and that 2'-dAdo in sublethal doses was teratogenic. We also examined the effects of 2'-dAdo on embryonic chicken SG and optic tectum in vivo to determine whether sublethal doses of 2'-dAdo produced cell death in these centers on E6 1/2 and 10. In the E6 1/2 SG, 2'-dAdo produced significant neuron loss (83%) and a decrease in SG volume (65%); however, at E10, there was only minor cell loss (7%) and no significant change in SG volume. In the optic tectum at E6 1/2, cell loss was confined mainly to the tectal ventricular zone, but there was little sign of cell loss in this organ at E10. Since cell production is vigorous in the SG and optic tectum at E6 1/2 but relatively low at E10, 2'-dAdo appears to work by stopping cell proliferation. The ineffectiveness of 2'-dAdo at E10 may result from the lethality of 2'-dAdo to the embryo at low concentrations (30 microM) in vivo, well below the apoptosis-inducing concentrations employed in vitro (100-300 microM). These data extend previous findings showing that purine and pyrimidine metabolism plays an important role in development.     

The effects of tectal lesion on the survival of isthmic neurones in Xenopus

The isthmic nucleus (IN) is a visual relay centre of the frog brain. It receives afferent projection from the optic tectum of the same side and projects bilaterally to both tecta. In young postmetamorphic Xenopus frogs, the survival of neurones in the IN on both sides was studied following the complete removal of the right tectum. In 6- to 8-week-old frogs, the right tectum was surgically removed and the operated animals allowed to survive for 1 to 13 weeks after operation. In selected animals, 3 days before the intended sacrifice, the postoptic commissure was transected and the cut isthmotectal fibres filled with horseradish peroxidase (HRP). In serial paraffin sections of the midbrain, the numbers of surviving and dying (pyknotic) neurones in the left and right IN were counted. The soma size of viable isthmic neurones and the volume of both IN were measured. Pyknotic neurones were seen between 1 and 6 weeks after operation in both the left and right IN, although the rate of cell loss was much greater in the latter. Virtually all the neurones of the right IN degenerated by 6 weeks after tectal ablation. In contrast, approximately 60% of neurones of the left IN survived. HRP histochemistry showed labelled isthmic neurones both in the left and right IN up to 3 weeks after operation. Thereafter, HRP-labelled neurones appeared only in the left IN. These observations indicate that the removal of the natural target of isthmic neurones brings about severe neurone death.(ABSTRACT TRUNCATED AT 250 WORDS)     

Retinofugal projections in the eel,Anguilla anguilla L. (Teleostei), visualized by the cobalt-filling technique

The retinofugal projections in the eel were studied by use of the cobalt-filling technique. The optic tract projects contralaterally to the hypothalamic optic nucleus, the anterior periventricular nucleus, the lateral geniculate nucleus, the dorsomedial optic nucleus, four pretectal recipient areas, the optic tectum, and the tegmentum. Small ipsilateral projections were demonstrated in the hypothalamic optic nucleus, the dorsomedial optic nucleus, and the optic tectum.     

Expression patterns of Ephs and ephrins throughout retinotectal development in Xenopus laevis

The Eph family of receptor tyrosine kinases and their ligands the ephrins play an essential role in the targeting of retinal ganglion cell axons to topographically correct locations in the optic tectum during visual system development. The African claw-toed frog Xenopus laevis is a popular animal model for the study of retinotectal development because of its amenability to live imaging and electrophysiology. Its visual system undergoes protracted growth continuing beyond metamorphosis, yet little is known about ephrin and Eph expression patterns beyond stage 39 when retinal axons first arrive in the tectum. We used alkaline phosphatase fusion proteins of EphA3, ephrin-A5, EphB2, and ephrin-B1 as affinity probes to reveal the expression patterns of ephrin-As, EphAs, ephrin-Bs, and EphBs, respectively. Analysis of brains from stage 40 to adult frog revealed that ephrins and Eph receptors are expressed throughout development. As observed in other species, staining for ephrin-As displayed a high caudal to low rostral expression pattern across the tectum, roughly complementary to the expression of EphAs. In contrast with the prevailing model, EphBs were found to be expressed in the tectum in a high dorsal to low ventral gradient in young animals. In animals with induced binocular tectal innervation, ocular dominance bands of alternating input from the two eyes formed in the tectum; however, ephrin-A and EphA expression patterns were unmodulated and similar to those in normal frogs, confirming that the segregation of axons into eye-specific stripes is not the consequence of a respecification of molecular guidance cues in the tectum.     

Diurnal expressions of four subtypes of melatonin receptor genes in the optic tectum and retina of goldfish

Four subtypes of melatonin receptor genes (Mel(1a) 1.4, Mel(1a) 1.7, Mel(1b), and Mel(1c)) are considered to be expressed to mediate various physiological functions of melatonin in goldfish (Carassius auratus). To examine their tissue distribution and diurnal changes in expression levels, we cloned partial gene fragments for these melatonin receptor subtypes, and established specific RT-PCR and quantitative real-time PCR systems. Mel(1a) 1.4 and Mel(1b) were predominantly expressed in various neuronal and peripheral tissues, while Mel(1a) 1.7 and Mel(1c) were expressed in the restricted tissues. All subtype genes were expressed in the optic tectum, diencephalon, mesencephalon, vagal lobe, retina and spleen. The real-time PCR analyses showed that significant differences among time were observed for Mel(1a) 1.4 in the optic tectum and for Mel(1a) 1.7 and Mel(1b) in the retina. In the retina, the levels of Mel(1a) 1.7 and Mel(1b) mRNAs showed diurnal changes with one peak at ZT24. The present results show differential distribution of four subtypes of melatonin receptor mRNAs in the neuronal and peripheral tissues. However, the expressions of all subtype genes in the retinorecipient brain regions and retina reinforce the role of the melatonin receptor in processing visual information. Furthermore, the present study demonstrates diurnal expressions of the major subtype genes, i.e. Mel(1a) 1.4 in the optic tectum and Mel(1a) 1.7 in the retina.     

GABA and development of the Xenopus optic projection

In the developing visual system of Xenopus laevis retinal ganglion cell (RGC) axons extend through the brain towards their major target in the midbrain, the optic tectum. Enroute, the axons are guided along their pathway by cues in the environment. In vitro, neurotransmitters have been shown to act chemotropically to influence the trajectory of extending axons and regulate the outgrowth of developing neurites, suggesting that they may act to guide or modulate the growth of axons in vivo. Previous work by Roberts and colleagues (1987) showed that populations of cells within the developing Xenopus diencephalon and mid-brain express the neurotransmitter gamma amino butyric acid (GABA). Here we show that Xenopus RGC axons in the midoptic tract grow alongside the GABAergic cells and cross their GABA immunopositive nerve processes. Moreover, RGC axons and growth cones express GABA-A and GABA-B receptors, and GABA and the GABA-B receptor agonist baclofen both stimulate RGC neurite outgrowth in culture. Finally, the GABA-B receptor antagonist CGP54626 applied to the developing optic projection in vivo causes a dose-dependent shortening of the optic projection. These data indicate that GABA may act in vivo to stimulate the outgrowth of Xenopus RGC axons along the optic tract.     

Alterations in concanavalin A binding during retinal development in Xenopus laevis]

Changes in concanavalin A binding were observed in the retina of Xenopus laevis throughout development. Prior to stage 37, the optic cup and nervous sysetm displayed a light, diffuse staining. Abruptly at stage 37, however, intense staining reaction occurred in the ganglionic fibers, both plexiform layers and photoreceptor inner segments, remaining thus throughout larval and adult life. Our results suggest that important structural modifications occur in retinal cells at the time of establishment of connections with the tectum, preceedings, and possibility related to, electrical functioning of the visual system.