Fibre organization and reorganization in the retinotectal projection of Xenopus

This study concerns the retinotopic organization of the ganglion cell fibres in the visual system of the frog Xenopus laevis. HRP was used to trace the pathways taken by fibres from discrete retinal positions as they pass from the retina, along the optic nerve and into the chiasma. The ganglion cell fibres in the retina are arranged in fascicles which correspond with their circumferential positions of origin. Within the fascicles the fibres show little age-related layering and do not have a strict radial organization. As the fascicles of fibres pass into the optic nerve head there is some exchange of position resulting in some loss of the retinal circumferential organization. The poor radial organization of the fibres in the retinal fascicles persists as the fibres pass through the intraocular part of the nerve. At a position just behind the eye there is a major fibre reorganization in which fibres arising from cells of increasingly peripheral retinal locations are found to have passed into increasingly peripheral positions in the nerve. Thus, fibres from peripheral-most retina are located at the nerve perimeter, whilst fibres from central retina are located in the nerve core. It is at this point that the radial, chronotopic, ordering of the ganglion cell axons, found throughout the rest of the optic pathway, is established. This annular organization persists along the length of the nerve until a position just before the nerve enters the brain. Here, fibres from each annulus move to form layers as they pass into the optic chiasma. This change in the radial organization appears to be related to the pathway followed by all newly growing fibres, in the most superficial part of the optic tract, adjacent to the pia. Just behind the eye, where fibres become radially ordered, the circumferential organization of the projection is largely lost. Fibres from every circumferential retinal position, which are of similar radial position, are distributed within the same annulus of the nerve. At the nerve-chiasma junction where each annulus forms a single layer as it enters the optic tract, there is a further mixing of fibres from all circumferential positions. However, as the fibres pass through the chiasma some active pathway selection occurs, generating the circumferential organization of the fibres in the optic tract. Additional observations of the organization of fibres in the optic nerve of Rana pipiens confirm previous reports of a dual representation of fibres within the nerve. The difference in the organization of fibres in the optic nerve of Xenopus and Rana pipiens is discussed.     

视网膜发育与形成的“镶嵌模型”

视网膜上不同种类的神经细胞为秩序分布.在胚胎发育过程中,如何能形成这种有秩序的空间分布对于眼睛和视网膜的发育至关重要.研究表明,眼睛和视网膜的发育与形成受多种基因的调控,不同的基因决定了视觉系统发育的不同结构.目前有报道认为,动物的眼睛在空间和时间上是由不同组织和不同分化的细胞镶嵌而形成的.     

Whole Retinal Explants from Chicken Embryos for Electroporation and Chemical Reagent Treatments

The retina is a good model for the developing central nervous system. The large size of the eye and most importantly the accessibility for experimental manipulations in ovo/in vivo makes the chicken embryonic retina a versatile and very efficient experimental model. Although the chicken retina is easy to target in ovo by intraocular injections or electroporation, the effective and exact concentration of the reagents within the retina may be difficult to fully control. This may be due to variations of the exact injection site, leakage from the eye or uneven diffusion of the substances. Furthermore, the frequency of malformations and mortality after invasive manipulations such as electroporation is rather high.This protocol describes an ex ovo technique for culturing whole retinal explants from chicken embryos and provides a method for controlled exposure of the retina to reagents. The protocol describes how to dissect, experimentally manipulate, and culture whole retinal explants from chicken embryos. The explants can be cultured for approximately 24 hr and be subjected to different manipulations such as electroporation. The major advantages are that the experiment is not dependent on the survival of the embryo and that the concentration of the introduced reagent can be varied and controlled in order to determine and optimize the effective concentration. Furthermore, the technique is rapid, cheap and together with its high experimental success rate, it ensures reproducibleresults. It should be emphasized that it serves as an excellent complement to experiments performed in ovo.     

The spatiotemporal transfer function of the Limulus lateral eye

The dynamics of the Limulus retina may be well described by the spatiotemporal transfer function, which measures the response of the eye to moving sinusoidal gratings. We consider a model for this system, which incorporates an excitatory generator potential, and self- and lateral inhibitory processes. Procedures are described which allow estimation of parameters for the model consistent with the empirical transfer function data. Transfer functions calculated from the model show good agreement with laboratory measurements, and may be used to predict accurately the response of the eye to arbitrary moving stimuli. The model allows convenient interpretation of the transfer function measurements in terms of physiological processes which underly the response of the Limulus retina.     

The origin and evolution of appendages

Current awareness of gene expression patterns and developmental mechanisms involved in the outgrowth and patterning of animal appendages contributes to our understanding of the origin and evolution of these body parts. Nevertheless, this vision needs to be complemented by a new adequate comparative framework, in the context of a factorial notion of homology. It may even be profitable to categorize as appendages also gut diverticula, body ingrowths and 'virtual appendages' such as the eye spots on butterfly wings. Another unwarranted framework is the Cartesian co-ordinate system onto which the appendages are currently described and where it is supposed that one patterning system exists for each separate Cartesian axis. It may be justified, instead, to look for correspondences between the appendages and the main body axis of the same animal, as the latter might be the source of the growth and patterning mechanisms which gave rise to the former. This hypothesis of axis paramorphisms is contrasted with the current hypothesis of gene co-option. Recapitulationism is a common fault in current Evo-Devo perspectives concerning the origin of the appendages, in that the evolutionary origin of appendages is often expected to be the same as one of the key mechanisms involved in the ontogenetic inception of appendage formation. This unwarranted perspective is also evident in the current debate on the nature of the default arthropod appendage. Most likely, a default arthropod appendage never did exist, as the first appendages probably developed along the trunk of an animal already patterned extensively along the antero-posterior body axis.     

Aldehyde dehydrogenase is a positional marker in the retina

An asymmetrically distributed protein in the embryonic mouse retina was identified as an aldehyde dehydrogenase through protein microsequencing. It was characterized as a cytosolic isoform with basic isoelectric point and preference for aliphatic substrates, features that resemble those of the isoform AHD-2 which is known to oxidize retinaldehyde to retinoic acid. Immunohistochemistry with aldehyde dehydrogenase antisera showed strong labeling of the dorsal retina from the early eye vesicle stage into adulthood. In addition, optic axons originating from the dorsal retina were transiently labeled during their outgrowth phase. Whereas in the embryo the enzyme was expressed in undifferentiated cells and in neurons, in the retina of the adult mouse the asymmetrically distributed isoform was mainly expressed in Müller glia, with the number of labeled glial cells varying with retinal position.     

The polar co-ordinate model for pattern regulation in epimorphic fields: A critical appraisal

The polar co-ordinate model for pattern regulation in epimorphic fields, as first proposed by French, Bryant & Bryant (1976), belongs to a general class of models employing two co-ordinates for describing the field value distribution over a monolayer of cells.I first analyse the constraints imposed by the use of polar co-ordinates for biological modelling. These constraints entail: distinction of the actual and derived spaces for the field with their specific and characteristic mapping modes; representation of the field value or a measure of the morphogenetic activity at various positions in the actual space by two polar co-ordinates—the phase or angle and the radius—in the derived space; and attribution of a singular property to the origin in the derived space, which ought to be mapped onto a putative field centre in the actual space.Upon reformulating the polar co-ordinate model while adhering to these constraints, one realizes that the choice of the shortest route between two points in the derived space applies only to the angular, and not to the radial, co-ordinate. Hence the shortest route between two points cannot be conceived as a straight line connecting them.If we assume that cells have certain limits in resolving differences in the field value, the field will virtually fall into territories of distinctive field values, each of which might encompass more than one cell; cells that lie within a single territory should be mutually interchangeable for prospective developmental pathways which may themselves diversify. The central postulate of the model is that disparate field values brought in apposition will induce a field value intercalation through cell proliferation to restore an unbroken sequence of field values for the newly emerging array of territories. This is assumed universally for the angular component of the field value but it need not apply to the radial component.It follows that angular territories meeting at the field centre will produce a central discontinuity of the field value, leading to a perpetual angular intercalation unless some theoretical provision is made. This may be resolved by any ad hoc hypotheses but also by introducing the concept of degeneracy towards the field centre of the angular co-ordinate down to three distinctive values at the innermost level of radial territories. One can then deduce and generalize various empirically recognized behaviours of epimorphic fields. These include the shortest intercalation rule (which may be modified into the more generally applicable, minor-in-major rule), and the distal transformation and so-called complete circle rules (which may now be unified into the more feasible distalization rule proposed by Bryant, French & Bryant, 1981).The models are assessed against various experimental observations mainly for theoretical consistency. A series of experimental tests for various theoretical alternatives are suggested. This work has simply explored the internal logic of the polar co-ordinate model and no suggestion is made, at this stage, to distinguish different families of alternative models for epimorphic systems on experimental grounds.     

Müller glia endfeet,a basal lamina and the polarity of retinal layers form properly in vitro only in the presence of marginal pigmented epithelium

Summary Dissociated embryonic chicken retinal cells regenerate in rotary culture into cellular spheres that consist of subareas expressing all three nuclear layers in an inside-out sequence (rosetted vitroretinae). However, when pigmented cells from the eye margin (peripheral retinal pigment epithelium) are added to the system, the sequence of layers is identical with that of an in-situ retina (laminar vitroretinae). In order to elucidate further the lamina-stabilizing effect exerted by the retinal pigment epithelium, we have compared both systems, laying particular emphasis on the ultrastructure of the basal lamina and of Müller glia processes. Ultrastructurally, in both systems, an outer limiting membrane, inner segments of photoreceptors and the segregation of cell bodies into three cell layers develop properly. Synapses are detectable in a premature state, although only in the inner plexiform layer of laminar vitroretinae. Although present in both systems, radial processes of juvenile Müller glia cells are properly fixed at their endfeet only in laminar vitroretinae, since a basal lamina is only expressed here. Large amounts of laminin are detected immunohistochemically within the retinal pigment epithelium and along a basal stalk that reaches inside the laminar vitroretinae. We conclude that the peripheral retinal pigment epithelium is essential for the expression of a basal lamina in vitro. Moreover, the basal lamina may be responsible both for stabilizing the correct polarity of retinal layers and for the final differentiation of the Müller cells.     

Embryonic malformations in a case of intrauterine parvovirus B19 infection

An incomplete embryo of 9 weeks development from a woman infected by human parvovirus B19 during early pregnancy was histologically examined. B19-DNA was detected in both embryonic and placental tissue by dot-blot hybridization. Focal vascular endothelial damage was found throughout the entire embryo and placenta together with mononuclear infiltrations around the vessels. In the placenta these mononuclear cells belonged for the greater part to the cytotoxic and/or suppressor T-cell group. One eye showed lens abnormalities and retinal folds. The other eye was microphthalmic and aphakic and showed dysplasia of the sclera, anterior segment, and retina. The skeletal muscle cells displayed a general eosinophilic degeneration. Focally, similar changes were found in heart muscle and smooth muscle tissue. In several tissues pathologic effects at a cellular level were noted, as intranuclear vacuole-like inclusions and nuclear ballooning. On the basis of this study it is concluded that human parvovirus B19 may affect several fetal tissues and may even have teratological effects on a developing human embryo.     

Nasotemporal asymmetry during teleost retinal growth: preserving an area of specialization.

Teleost fish retinas grow throughout adult life through both cell addition and stretching. Cell division occurs at the periphery of the retina, resulting in annular addition of all cell types except rod photoreceptors, which are added in the central retina. Since many teleosts have a region of high cellular density at the temporal pole of the eye, we analyzed whether and how this specialized region of high visual acuity maintained its relative topographical position through asymmetric circumferential growth. To do this, we measured the pattern of long-term retinal growth in the African cichlid Haplochromis burtoni. We found that the retina expands asymmetrically along the nasotemporal axis, with the nasal retina growing at a higher rate than the temporal, dorsal, or ventral retinae, whose growth rates are equal. This nasotemporal asymmetry is produced via significantly greater expansion of retinal tissue at the nasal pole rather than through differential cell proliferation. The mechanisms responsible for this differential retinal enlargement are unknown; however, such asymmetric expansion very likely minimizes disruption in vision during rapid growth.     

The effect of elastin damage on the mechanics of the aortic valve

Porcine bioprosthetic heart valves degenerate and fail mechanically through a mechanism that is currently not well understood. It has been suggested that damage to the elastin component of prosthetic valve cusps could be responsible for changes in the mechanical function of the valve that would predispose it to increased damage and ultimate failure. To determine whether damage to elastin can produce the structural and mechanical changes that could initiate the process of bioprosthetic valve degeneration, we developed an elastase treatment protocol that fragments elastin and negates its mechanical contribution to the valve tissue. Valve cusps were mechanically tested before and after digestion to measure the mechanical changes resulting from elastin damage. Elastin damage produced a decrease in radial and circumferential extensibility (from 43 to 18% strain radially and 12 to 7% strain circumferentially), with a slight increase in stiffness (1.3-2.6kN/m for radial and 10.6-11.9kN/m for circumferential directions). Digestions with trypsin, which does not cleave elastin, confirmed that the changes in mechanics of the circumferential samples were likely due to the nonspecific removal of proteoglycans by elastase, while the changes in the radial samples were indeed due to elastin damage. Removing the mechanical contribution of elastin alters the mechanical behavior of the aortic valve cusp, primarily in the radial direction. This finding implies that damage to elastin will distend the cusps, reduce their extensibility, and increase their stiffness. Damage to elastin may therefore contribute to the degeneration and failure of prosthetic valves.     

Retinoic acid is required for specification of the ventral eye field and for Rathke's pouch in the avian embryo

We have investigated the role of retinoic acid (RA) in eye development using the vitamin A deficient quail model system, which overcomes problems of retinoic acid synthesising enzyme redundancy in the embryo. In the absence of retinoic acid, the ventral optic stalk and ventral retina are missing, whereas the dorsal optic stalk and dorsal retina develop appropriately. Other ocular abnormalities observed were a thinner retina and the lack of differentiation of the lens. In an attempt to explain this, we studied the expression of various dorsally and ventrally expressed genes such as Pax2, Pax6, Tbx6, Vax2, Raldh1 and Raldh3 and noted that they were unchanged in their expression patterns. In contrast, the RA catabolising enzymes Cyp26A1 and Cyp26B1 which are known to be RA-responsive were not expressed at all in the developing eye. At much earlier stages, the expression domain of Shh in the prechordal plate was reduced, as was Nkx2.1 and we suggest a model whereby the eye field is specified according to the concentration of SHH protein that is present. We also describe another organ, Rathke's pouch which fails to develop in the absence of retinoic acid. We attribute this to the down-regulation of Bmp2, Shh and Fgf8 which are known to be involved in the induction of this structure.     

Nasotemporal asymmetry during teleost retinal growth: preserving an area of specialization

Teleost fish retinas grow throughout adult life through both cell addition and stretching. Cell division occurs at the periphery of the retina, resulting in annular addition of all cell types except rod photoreceptors, which are added in the central retina. Since many teleosts have a region of high cellular density at the temporal pole of the eye, we analyzed whether and how this specialized region of high visual acuity maintained its relative topographical position through asymmetric circumferential growth. To do this, we measured the pattern of long‐term retinal growth in the African cichlid Haplochromis burtoni. We found that the retina expands asymmetrically along the nasotemporal axis, with the nasal retina growing at a higher rate than the temporal, dorsal, or ventral retinae, whose growth rates are equal. This nasotemporal asymmetry is produced via significantly greater expansion of retinal tissue at the nasal pole rather than through differential cell proliferation. The mechanisms responsible for this differential retinal enlargement are unknown; however, such asymmetric expansion very likely minimizes disruption in vision during rapid growth. © 1999 John Wiley & Sons, Inc. J Neurobiol 41: 435–442, 1999     

Effects of retinal dopamine depletion on the growth of the fish eye

We investigated the suitability of fishes as animal models to study the involvement of the retinal dopaminergic system in the visually guided control of eye growth (emmetropization). Advantages of such a model system are (i) that all dopaminergic cells in the retina can be destroyed without apparent damage to other neurons, (ii) simple optical design and short depth of field of the eye, and (iii) continuous growth throughout life. Depleting the retina of dopamine in Aequidens pulcher (Cichlidae) had no apparent effect on refractive state, since size and focal length of the eye were reduced by the same amount. Furthermore, imposed defocus was compensated at a normal rate in spite of the absence of retinal dopamine. In A. pulcher, the dopaminergic system of the retina thus appears not to have an essential role in emmetropization. Our results furthermore suggest that in eyes of more complicated optical design, manipulation of the retinal dopaminergic system may lead to unrelated effects indistinguishable from direct interference with emmetropization. A major disadvantage of the fish model was that refractive state of the eye could not be measured accurately in vivo with standard methods. Accepted: 9 January 1999     

Noggin producing, MyoD-positive cells are crucial for eye development

A subpopulation of cells expresses MyoD mRNA and the cell surface G8 antigen in the epiblast prior to the onset of gastrulation. When an antibody to the G8 antigen was applied to the epiblast, labeled cells were later found in the ocular primordia and muscle and non-muscle forming tissues of the eyes. In the lens, retina and periocular mesenchyme, G8-positive cells synthesized MyoD mRNA and the bone morphogenetic protein inhibitor Noggin. MyoD expressing cells were ablated in the epiblast by labeling them with the G8 MAb and lysing them with complement. Their ablation in the epiblast resulted in eye defects, including anopthalmia, micropthalmia, altered pigmentation and malformations of the lens and/or retina. The right eye was more severely affected than the left eye. The asymmetry of the eye defects in ablated embryos correlated with differences in the number of residual Noggin producing, MyoD-positive cells in ocular tissues. Exogenously supplied Noggin compensated for the ablated epiblast cells. This study demonstrates that MyoD expressing cells serve as a Noggin delivery system to regulate the morphogenesis of the lens and optic cup.     

Elimination of egg pigment from developing ocular tissues in the frog Rana pipiens

The method by which egg pigment is eliminated from the developing retina, corneal epithelium and lens in Rana pipiens was studied with light and electron microscopy. The retina expells egg pigment into the space between the retina and pigment epithelium. This pigment is then engulfed by the pigment epithelial cells. The corneal epithelium eliminates egg pigment directly to the outside via the free surface of the epithelial cells. Egg pigment accumulates in a few cells in the lens. These cells probably degenerate and are extruded. These ectodermal derivatives in the eye are free of egg pigment long before ectodermal derivatives in other parts of the embryo lose their pigment. The early elimination of egg pigment from ocular tissues may related to the fact that these tissues must be transparent in order that light may pass freely to the photoreceptors.     

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.