Formation of the retinal ganglion cell and optic fiber layers

The early development of retinal ganglion cell and the optic fiber layers has been studied by examining the morphology of differentiating retinal ganglion cells using immunoelectron microscopy and a monoclonal antibody against neuron-specific beta-tubulin. This antibody identified retinal ganglion cells during the stages of their most active differentiation and axonogenesis prior to maturation of other retinal neurons. The changing morphology of retinal ganglion cells during these early stages is consistent with a differentiation sequence in which axonogenesis and translocation of the cell body to the vitreal surface occur while the cell is still attached to the vitreal margin through its vitreal endfeet. Thus, the mechanism of retinal ganglion cell axon generation and soma migration to the vitreal surface appears to involve maintenance of this attachment which may act as both a focus for axon differentiation and an anchor for directed nuclear translocation to the vitreal margin.     

The role of bone morphogenetic proteins in the differentiation of the ventral optic cup

The ventral region of the chick embryo optic cup undergoes a complex process of differentiation leading to the formation of four different structures: the neural retina, the retinal pigment epithelium (RPE), the optic disk/optic stalk, and the pecten oculi. Signaling molecules such as retinoic acid and sonic hedgehog have been implicated in the regulation of these phenomena. We have now investigated whether the bone morphogenetic proteins (BMPs) also regulate ventral optic cup development. Loss-of-function experiments were carried out in chick embryos in ovo, by intraocular overexpression of noggin, a protein that binds several BMPs and prevents their interactions with their cognate cell surface receptors. At optic vesicle stages of development, this treatment resulted in microphthalmia with concomitant disruption of the developing neural retina, RPE and lens. At optic cup stages, however, noggin overexpression caused colobomas, pecten agenesis, replacement of the ventral RPE by neuroepithelium-like tissue, and ectopic expression of optic stalk markers in the region of the ventral retina and RPE. This was frequently accompanied by abnormal growth of ganglion cell axons, which failed to enter the optic nerve. The data suggest that endogenous BMPs have significant effects on the development of ventral optic cup structures.     

Eye formation in the absence of retina

Eye development is a complex process that involves the formation of the retina and the lens, collectively called the eyeball, as well as the formation of auxiliary eye structures such as the eyelid, lacrimal gland, cornea and conjunctiva. The developmental requirements for the formation of each individual structure are only partially understood. We have shown previously that the homeobox-containing gene Rx is a key component in eye formation, as retinal structures do not develop and retina-specific gene expression is not observed in Rx-deficient mice. In addition, Rx−/− embryos do not develop any lens structure, despite the fact that Rx is not expressed in the lens. This demonstrates that during normal mammalian development, retina-specific gene expression is necessary for lens formation. In this paper we show that lens formation can be restored in Rx-deficient embryos experimentally, by the elimination of β-catenin expression in the head surface ectoderm. This suggests that β-catenin is involved in lens specification either through Wnt signaling or through its function in cell adhesion. In contrast to lens formation, we demonstrate that the development of auxiliary eye structures does not depend on retina-specific gene expression or retinal morphogenesis. These results point to the existence of two separate developmental processes involved in the formation of the eye and its associated structures. One involved in the formation of the eyeball and the second involved in the formation of the auxiliary eye structures.     

Ocular dimensions and cone photoreceptor topography in adult Nile Tilapia <Emphasis Type="Italic">Oreochromis niloticus</Emphasis>

Information on the anatomy of the eye and the topography of cone photoreceptor cells in the retina is presented for the Nile Tilapia (Oreochromis niloticus). In adults, the shape and proportions of the ocular components of the prominent eye conform to the general form of fish eyes, as determined using cryo-sectioned eyes. The lens is approximately spherical and there is little variation in the distance from the centre of the lens to the border between the choroid and retina at a range of angles about the optical axis. The average ratio of the distance from the centre of the lens to the retina: lens radius (Matthiessen’s ratio) is 2.44:1. In retinal wholemounts, single and double (twin) cone photoreceptors, forming a square mosaic, are present. Peak photoreceptor densities for both morphological cone types are found in the temporal retina. Using peak cone densities and estimates of focal length from cryo-sectioned eyes, visual acuity is calculated to be 5.44 cycles per deg. The lack of apparent specific ocular or retinal specializations and the relatively low visual acuity reflect the lifestyle of the Nile Tilapia and may allow it to adapt to changes in visual environment in its highly variable natural habitat as well as contributing to the ‘ecological flexibility’ of this species.     

Induction of the Eye Lens

In general terms embryonic induction involves the association of embryonic tissues and leads to tissue differentiation. It is one of the known essential processes leading to the normal development of embryos. However, despite its importance, very little is known about the mechanisms of inductive interactions. For example, what is the nature of communication between tissues, how does this communication effect the synthetic activity of the cells, and once a new pattern of synthesis has been established how is the sequence of events leading to tissue differentiation co-ordinated? The answers to these questions will come only from the intensive study of inductive interactions and tissue differentiation at all levels from the morphological to the molecular.
One of the best known examples of induction, at least superficially, is the differentiation of lens from head ectoderm after its interaction with optic vesicle. The popularity of this tissue with embryologists may be attributed to its accessibility of manipulation because of its position on the outside of the embryo. In addition, its distinct morphology and specific biochemical composition make it relatively easy to determine whether the lens differentiates after experimental treatment. About the turn of this century lens differentiation was thought to depend on the specific interaction of just two embryonic tissues, head ectoderm and neuro-ectoderm (optic vesicle). However, experimental analysis since then has revealed that this oversimplified view of lens induction is incorrect. In fact there is evidence that a large number of other tissues besides embryonic head ectoderm can differentiate into lens and that other conditions besides the presence of optic vesicle can induce lens differentiation. The purpose of this work is to review the evidence on lens induction and based on this, to determine what we know about the mechanism(s) controlling this process.     

Cellular and ultrastructural features of the regenerating adult eye in the marine gastropod llyanassa obsoleta

Light and electron microscopic techniques were used to study the cellular and ultrastructural components of the regenerating adult eye of the marine prosobranch gastropod Ilyanassa obsoleta. Behavioral tests were used to determine return of vision in animals with generated eyes. As early as 3 days after removal of the adult eye, the regenerating eye primordium appeared as a pigmented mass of cells that invaginated from the surface epithelium in the area of the wound. Twelve days after eye removal, the regenerating eye was very similar to the postmetamorphic juvenile eye and to the adult eye: It contained a retinal layer, as well as an extracellular lens, cornea, connective tissue capsule, and forming optic nerve; vision had returned. Growth of the eye and its components was linear; size ratios established among forming eye components were maintained during growth. The events of eye regeneration appear to recapitulate embryonic eye formation. The sequence of invagination, pigmentation, and lens, optic nerve, and retinal pattern formation are similar.     

Inferred positive phototropic activity in human photoreceptors

The Stiles-Crawford (S.-C.) function, a measure of the directional sensitivity of the retina, was used to infer the alignment characteristics of the sampled retinal elements. One assumes that the peak of the photopic S.-C. function reflects the central alignment tendency of renal elements sampled, and that the shape of the function reflects, among other factors, distributive qualities. Here two tests were performed to determine whether the function sampled reflected positive phototropic activity. The natural eye pupil was dilated and artificial pupils were substituted having specified eccentricity from the centre of the natural pupil. This was achieved with a displaced iris contact lens. After a series of complex experiments, it was finally shown that the peaks of the S.-C. function shifted towards the displaced aperture of the contact lens. As a second test, individuals were occluded uniocularly with a black patch for periods of time up to 10 days. This caused remarkable flattening of the measured S.-C. function. That flattening occurred in determinations of both photopic and scotopic S.-C. functions. Comparable effects were not seen in the second eye or if a diffuser was substituted for the black patch. Change and recovery in both experiments occurred within 3-5 days. On the basis of these experiments it is inferred that there is an active mechanism behaving in a positive phototropic manner present in the human retina.     

Eye Structure and Vision in the Freshwater Pulmonate Mollusc Planorbarius corneus

The structure of the mollusc Planorbarius corneus eye was studied using light and electron microscopy. The eye consists of the cornea, eye lens of non-spherical shape, and the vitreous body tightly bound to it, as well as of a monolayer non-inverted retina composed of photoreceptor and supporting (pigmented) cells. Its inner surface has two invaginations. The apices of several hundreds of photoreceptors directed to the vitreous body have groups of microvilli with a parallel orientation to each other. The eye optic system places the image into the base of the retinal microvillar layer. Its angle resolution provided by density of distribution of photoreceptor cells and the value of the index F = 1.71 is to be about 2.06° with a correction for the light spreading between microvilli of neighbor cells. Under conditions of a V-shaped labyrinth, the P. corneus molluscs show positive phototaxis by moving to the light source. The angular acuity of vision was assessed from differences in the choice by the molluscs of direction of movement to the pattern of vertical black bands with different periods of alternation. The differential threshold obtained is within an interval of 1.43–1.91°, which is close to the calculated value of angular resolution of the retina.     

Eye morphology and optics of the double-eyed mysid Euchaetomera typica

The structure and optics of the mesopelagic double-eyed mysid crustacean Euchaetomera typica Sars, 1884 are described for the first time. The lateral eye is a typical refracting superposition eye with a wide field of view (172°) and low resolution (interommatidial angle of 7.3°). The antero-dorsal part of the eye is elongated due to the extension of the clear zone. This dorsal eye has a restricted field of view (33°) but much higher resolution (1.5°). The dorsal eye also uses refracting superposition optics, although the optical array is unusual as many of the peripheral ommatidia lack crystalline cones. The centre of curvature of the cornea is in front of the flattened rhabdom layer whereas the axes of the crystalline cones are centred on a point about twice as deep as the rhabdom layer. This results in a well-focused eye, free of spherical aberration. There is a remarkable similarity in eye structure between this species and some mesopelagic double-eyed euphausiid crustaceans.     

Bilateral retinal projections in the black piranah (Serrasalmus niger)

Summary The retinal projections were studied in the black piranah (Serrasalmus niger) with degeneration and autoradiographic methods. The projections are bilateral to the hypothalamic optic nucleus, the dorsomedial optic nucleus, corpus geniculatum ipsum of Meader (1934) and the optic tectum. Unilateral, crossed projections were traced to the pretectal nucleus and the cortical nucleus. The visual system of the black piranah is exceptionally well developed but has retained many primitive features including the extensive bilateral projections.     

Electron microscopic observations on the pecten of the great blue heron (Ardea herodias).

The pecten oculi of the great blue heron (Ardea herodias) has been examined by both light and electron microscopy. In this species the pecten is large and of the pleated type. It consists of 14-15 acordion folds that are joined apically by a more heavily pigmented bridge of tissue which holds the pecten in a fan-like shape widest at its base. As in other species it is situated over the optic nerve head and projects out into the vitreous. Within each fold are numerous capillaries, larger supply and drainage vessels and many melanocytes. The capillaries are extremely specialized vessels which display extensive microfolds on both their luminal and abluminal borders. The endothelial cell bodies are extremely thin with most organelles present in a paranuclear location. The capillaries are surrounded by thick fibrillar basal laminae which are felt to be structurally useful. Pericytes are a common feature of these capillaries. The numerous pleomorphic melanocytes which form an incomplete sheath around the capillaries and other blood vessels are also felt to be important in structural support of the pecten. The morphology of the pecten of the great blue heron is indicative of a heavy involvement in the transport of materials.     

The lens controls cell survival in the retina: Evidence from the blind cavefish Astyanax

The lens influences retinal growth and differentiation during vertebrate eye development but the mechanisms are not understood. The role of the lens in retinal growth and development was studied in the teleost Astyanax mexicanus, which has eyed surface-dwelling (surface fish) and blind cave-dwelling (cavefish) forms. A lens and laminated retina initially develop in cavefish embryos, but the lens dies by apoptosis. The cavefish retina is subsequently disorganized, apoptotic cells appear, the photoreceptor layer degenerates, and retinal growth is arrested. We show here by PCNA, BrdU, and TUNEL labeling that cell proliferation continues in the adult cavefish retina but the newly born cells are removed by apoptosis. Surface fish to cavefish lens transplantation, which restores retinal growth and rod cell differentiation, abolished apoptosis in the retina but not in the RPE. Surface fish lens deletion did not cause apoptosis in the surface fish retina or affect RPE differentiation. Neither lens transplantation in cavefish nor lens deletion in surface fish affected retinal cell proliferation. We conclude that the lens acts in concert with another optic component, possibly the RPE, to promote retinal cell survival. Accordingly, deficiency in both optic structures may lead to eye degeneration in cavefish.     

Persistent hyperplastic primary vitreous

Persistent hyperplastic primary vitreous (PHPV) is a common congenital developmental anomaly of the eye that results following failure of the embryological, primary vitreous and hyaloid vasculature to regress. It typically presents unilaterally without associated systemic findings. Although the etiology is assumed to be identical in each of its three variants, PHPV is still subclassified into three presentations. The purely anterior presentation of PHPV is also known as persistent tunica vasculosa lentis and persistent posterior fetal fibrovascular sheath of the lens. It occurs in eyes with pathology of the anterior segment. This form typically involves cataract, glaucoma and a retrolenticular membrane. The purely posterior presentation of PHPV is termed falciform retinal septum and ablatio falcicormis congentia. It occurs in eyes with abnormalities confined to the posterior segment such as retinal folds, vitreal stalk, vitreal membranes, macular abnormalities and optic disc abnormalities. A combination of anterior and posterior presentations is the most commonly seen clinical presentation. Case report. We present a case in which an 11-year old male was referred to our office for reevaluation of a large angle esotropia, strabismic and deprivational amblyopia and previously diagnosed PHPV, OD. Conclusion. Without treatment, PHPV can produce recurrent intraocular hemorrhage, secondary glaucoma and eventually require enucleation. Early surgical intervention is necessary to prevent progressive pathologic changes and to obtain the best visual results. Finally, while PHPV is a documented source of leukocoria, clinicians should be aware of differential diagnoses which involve the white pupil (congenital cataract, retinoblastoma, Norrie's disease, retinopathy of prematurity, retinal detachment and Coat's disease).     

Developmental changes of carbonic anhydrase in the retina of the mouse: a histochemical study

Synopsis In the optic cup of early mouse embryos, carbonic anhydrase activity is seen only in the pigment epithelial cells. During the late prenatal period the enzyme appears in the Müller cells, first in the perikarya. During the postnatal development the enzyme activity appears in the radial processes of the Müller cells starting at the vitreal border along with the separation of the outer retinal layers. This is followed by increased activity in the plexiform layers, presumably in the lateral processes. Carbonic anhydrase localization in pigment epithelial and Müller cells attains the adult pattern at about 16 days corresponding with the initiation of retinal function.     

CHOLINE ACETYLTRANSFERASE (ChAc) ACTIVITY IN DEVELOPING CHICK OPTIC CENTRES AND THE EFFECTS OF MONOLATERAL REMOVAL OF RETINA AT AN EARLY EMBRYONIC STAGE AND AT HATCHING

The choline acetyltransferase (ChAc) activity was measured in the optic centres of chick embryos after early removal of the optic cup and of young chicks after monolateral extirpation of the right eyeball after hatching. The contralateral optic lobes were thus deprived of their complement of retinal fibres. The following results were obtained: in chick embryos the ChAc was slightly lower in the deafferented lobe between the 10th and the 14th day of incubation; between the 14th and the 17th day a critical fall in activity was observed leading to a significant ChAc loss of 71 per cent. In eye deprived chicks no significant change in total ChAc activity occurred during the first postoperative month; significant changes were found only in the second month. The results reached so far suggest that removal of retinal fibres does not cause short term changes in optic centre ChAc in either the embryo or the chick. ChAc contained in nerve cell bodies seems independent of synapses and its behaviour is interpreted as a reflection of metabolic disturbance of the centre.     

Adrenergic Nerves in the Avian Eye and Ciliary Ganglion

Summary The distribution of adrenergic fibres to the eye and to the ciliary ganglion was studied in pigeons, chicken and ducks with the aid of the sensitive and highly specific fluorescence method of Falck and Hillarp. In some animals the intensity of the fluorescence was increased by treating the animals with Nialamide and 1-DOPA. The cornea contained no adrenergic fibres except at the limbus, where a plexus of adrenergic varicose fibres was seen, partly associated with vessels. In the chamber angle, adrenergic varicose fibres were common in the loose connective tissue covering the canal of Schlemm. The canal of Schlemm was supplied by only few adrenergic fibres, but such fibres appeared along the intrascleral aqueous drainage vessels. In the iris, adrenergic varicose fibres appeared immediately in front of the posterior layer of pigment cells, strongly indicating the presence of a dilator homologous with that seen in mammals. The frontal third of the stroma contained several adrenergic varicose fibres, many of which seemed to lack association with any vessel. Varicose adrenergic fibres were also sparsely seen in the striated muscle of the iris. The ciliary processes contained many adrenergic varicose fibres, at least part of which seemed to be associated with the ciliary epithelium. The striated muscles of the ciliary body contained adrenergic varicose fibres along the vessels only. The retina contained adrenergic varicose fibres in three layers in the inner plexiform layer. Adrenergic ganglion cells of two sizes were detected in the inner nuclear layer. The retinal vessels had no adrenergic nerve fibres. The pecten was also devoid of adrenergic nerve fibres, except along the vessels close to the papilla. The optic nerve contained adrenergic varicose nerve fibres along vessels only. In the ciliary ganglion, varicose adrenergic fibres appeared at the small ganglion cells, often forming baskets of synaptic character.Acknowledgements. The work has been supported by the United States Public Health Service (grant NB 06701-01), by the Swedish Medical Research Council (project B 67-12 X-712-02 A) and by the Faculty of Medicine, University of Lund, Sweden.     

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.     

Microdissection of Zebrafish Embryonic Eye Tissues

Zebrafish is a popular animal model for research on eye development because of its rapid ex utero development and good fecundity. By 3 days post fertilization (dpf), the larvae will show the first visual response. Many genes have been identified to control a proper eye development, but we are far from a complete understanding of the underlying genetic architecture. Whole genome gene expression profiling is a useful tool to elucidate genetic regulatory network for eye development. However, the small size of the embryonic eye in zebrafish makes it challenging to obtain intact and pure eye tissues for expression analysis. For example, the anterior-posterior length of the eye between day 2 and 3 is only approximately 200-300 μm, while the diameter of the lens is less 100 μm. Also, the retinal pigment epithelium (RPE) underlying the retina is just a single-layer epithelium. While gene expression profiles can be obtained from the whole embryo, they do not accurately represent the expression of these tissues. Therefore pure tissue must be obtained for a successful gene expression profiling of eye development. To address this issue, we have developed an approach to microdissect intact retina and retina with RPE attached from 1-3 dpf, which cover major stages of eye morphogenesis. All procedures can be done with fine forceps and general laboratory supplies under standard stereomicroscopes. For retinal dissection, the single-layer RPE is removed and peeled off by brushing action and the preferential adherence of the RPE remnants to the surface of the culture plate for dissection. For RPE-attached retinal dissection, the adherence of RPE to the dissection plate is removed before the dissection so that the RPE can be completely preserved with the retina. A careful lifting action of this tissue can efficiently separate the presumptive choroid and sclera. The lens can be removed in both cases by a chemically etched tungsten needle. In short, our approach can obtain intact eye tissues and has been successfully utilized to study tissue-specific expression profiles of zebrafish retina^{1, 2} and retinal pigment epithelium³.Download video file.^{(105M, mp4)}     

Lens Transplantation in Zebrafish and its Application in the Analysis of Eye Mutants

The lens plays an important role in the development of the optic cup^[1,2]. Using the zebrafish as a model organism, questions regarding lens development can be addressed. The zebrafish is useful for genetic studies due to several advantageous characteristics, including small size, high fecundity, short lifecycle, and ease of care. Lens development occurs rapidly in zebrafish. By 72 hpf, the zebrafish lens is functionally mature ^[3]. Abundant genetic and molecular resources are available to support research in zebrafish. In addition, the similarity of the zebrafish eye to those of other vertebrates provides basis for its use as an excellent animal model of human defects^[4-7]. Several zebrafish mutants exhibit lens abnormalities, including high levels of cell death, which in some cases leads to a complete degeneration of lens tissues ^[8]. To determine whether lens abnormalities are due to intrinsic causes or to defective interactions with the surrounding tissues, transplantation of a mutant lens into a wild-type eye is performed. Using fire-polished metal needles, mutant or wild-type lenses are carefully dissected from the donor animal, and transferred into the host. To distinguish wild-type and mutant tissues, a transgenic line is used as the donor. This line expresses membrane-bound GFP in all tissues, including the lens. This transplantation technique is an essential tool in the studies of zebrafish lens mutants.Open in a separate windowClick here to view.^{(64M, flv)}