The retinal pigment epithelium of the eye regulates the development of scleral cartilage

The majority of vertebrate species have a layer of hyaline cartilage within the fibrous sclera giving an extra degree of support to the eyeball. In chicks, this is seen as a cuplike structure throughout the scleral layer. However, the mechanisms that control the development of scleral cartilage are largely unknown.Here we have studied the phases of scleral cartilage development and characterised expression profiles of genes activated during the cartilage differentiation programme. CART1 and SOX9, the earliest markers of pre-committed cartilage, are expressed in the mesenchyme surrounding the optic cup. Later AGGRECAN, a matrix protein expressed during chondrocyte differentiation, is also expressed. The expression of these genes is lost following early removal of the optic cup, suggesting a role for this tissue in inducing scleral cartilage. By grafting young retinal pigment epithelium (RPE) and retina into cranial mesenchyme in vivo, it was found that RPE alone has the ability to induce cartilage formation.There are some exceptions within the vertebrates where scleral cartilage is not present; one such example is the placental mammals. However, we found that the cartilage differentiation pathway is initiated in mice as seen by the expression of Cart1 and Sox9, but expression of the later cartilage marker Aggrecan is weak. Furthermore, cartilage forms in mouse peri-ocular mesenchyme micromass culture. This suggests that the process halts in vivo before full differentiation into cartilage, but that murine scleral mesenchyme has retained the potential to make cartilage in vitro.RA, Wnts and Bmps have been linked to the cartilage development process and are expressed within the developing RPE. We find that RA may have a role in early scleral cartilage development but is not likely to be the main factor involved.These data reveal the course of scleral cartilage formation and highlight the key role that the optic cup plays in this process. The driving element within the optic cup is almost certainly the retinal pigmented epithelium.     

Growth of the eye and pigment epithelium of the retina during postnatal development of rats]

By the weight changes, the rat's eye grows during the whole life, whereas its scleral sector with the area equal to that of pigment epithelium of the retina grows most intensively between the 2nd and 5th days after birth. During this period, its weight attains half of the value characteristic of the scleral sector for one year old rats. This period of growth of the scleral sector coincides with the previously established peak of proliferative activity and appearance of first binuclear cells in the pigment epithelium. From the 5th day till the 12th month after birth, the weight of scleral sector increases twice and its area 6 times. This suggests that the mechanical tension of the scleral sector walls is one of the factors of growth of this eye part. On the basis of comparison of the scleral sector growth, changes in proliferative activity and number of polyploid cells in the pigment epithelium of the central zone of fundus oculi, the following periodization of the life cycle of cell population of the pigment epithelium is proposed: (1) from birth till the 15th day--period of principal determination (the number of binuclear tetraploid cells attains 80%), (2) from the 15th day till, at least, the 5th month--period of stabilization, (3) after 5 months--period of senescence characterized by the accumulation of highly ploid tri- and tetranuclear cells; its lower limit is not clearly defined.     

CNPase activity in the vertebrate retina, retinal pigmented epithelium, and choroid

The activity of the enzyme 2',3'-cyclic nucleotide 3'-phosphohydrolase (CNPase, E.C.3.1.4.37) has been studied in the retina of three vertebrate species. Activity was highest in the goldfish, followed by Xenopus laevis and Rana pipiens. Also, high activity levels were found in goldfish retinal pigment epithelium and choroid, but not in the other two species. When added to in vitro culture systems, 2',3'-cyclic nucleotides were found to have no effect on goldfish cone retinomotor movement, but caused a marked inhibition of Rana pipiens rod outer segment disc membrane shedding. It is suggested that CNPase may play a role in cellular processes requiring membrane structural reorganization.     

The retinal pigment epithelium as a gateway for monocyte trafficking into the eye

The choroid plexus epithelium within the brain ventricles orchestrates blood‐derived monocyte entry to the central nervous system under injurious conditions, including when the primary injury site is remote from the brain. Here, we hypothesized that the retinal pigment epithelium (RPE) serves a parallel role, as a gateway for monocyte trafficking to the retina following direct or remote injury. We found elevated expression of genes encoding leukocyte trafficking determinants in mouse RPE as a consequence of retinal glutamate intoxication or optic nerve crush (ONC). Blocking VCAM‐1 after ONC interfered with monocyte infiltration into the retina and resulted in a local pro‐inflammatory cytokine bias. Live imaging of the injured eye showed monocyte accumulation first in the RPE, and subsequently in the retina, and peripheral leukocytes formed close contact with the RPE. Our findings further implied that the ocular milieu can confer monocytes a phenotype advantageous for neuroprotection. These results suggest that the eye utilizes a mechanism of crosstalk with the immune system similar to that of the brain, whereby epithelial barriers serve as gateways for leukocyte entry.     

Combinatorial signaling in the specification of primary pigment cells in the Drosophila eye

In the developing eye of Drosophila, the EGFR and Notch pathways integrate in a sequential, followed by a combinatorial, manner in the specification of cone-cell fate. Here, we demonstrate that the specification of primary pigment cells requires the reiterative use of the sequential integration between the EGFR and Notch pathways to regulate the spatiotemporal expression of Delta in pupal cone cells. The Notch signal from the cone cells then functions in the direct specification of primary pigment-cell fate. EGFR requirement in this process occurs indirectly through the regulation of Delta expression. Combined with previous work, these data show that unique combinations of only two pathways--Notch and EGFR--can specify at least five different cell types within the Drosophila eye.     

Clonal analysis of the development of the pigment epithelium of the eye in chimeric or/or----AKR mice

The development of cell clones was studied in the retinal pigment epithelium of chimaeric mice or/or----AKR. The clonal analysis suggests that on the 13th day of gestation the cells in the retinal pigment epithelium are distributed almost randomly while in the adults they are grouped in small coherent clones. In the retinal pigment epithelium the AKR cell predominated over the or/or cells. The interaction of mutant and normal clones during the eye development leads, in most cases, to the normalization of eyes in chimaeras. Cases of microphthalmia and asymmetry in distribution of clones suggest irregular and random distribution of these clones in the embryo.     

A novel antigen is shared by retinal pigment epithelium and pigmented neural crest

 Pigment cells in vertebrate embryos are formed in both the central and peripheral nervous system. The neural crest, a largely pluripotent population of precursor cells derived from the embryonic neural tube, gives rise to pigment cells which migrate widely in head and trunk.The retinal pigment epithelium is derived from the optic cup, which arises from ectoderm of the neural tube. We have generated an antibody, ips6, which stains an antigen common to pigment cells of retinal pigment epithelium and neural crest. Ips6 stains retinal pigment epithelium and choroid as well as a subset of crest cells that migrate in pathways typical of melanoblasts. Immunoreactivity is seen first in the eye and later in a subset of migrating crest cells. Crest cells in the amphibian embryo migrate along specific, stereotyped routes; ips6 immunoreactive cells are found in some but not all of these pathways. In older wild-type embryos, cells expressing ips6 appear coincident with pigment-containing cells in the flank, head, eye and embryonic gut. In older animals, staining in the eye extends to the intraretinal segment of optic nerve and interstices between photoreceptors and cells at the retinal periphery. We suggest that the ips6 antibody defines an antigen common to pigment cells of central and peripheral origin. Received: 22 January 1996/Accepted: 15 July 1996     

Role of cell interactions in ascidian muscle and pigment cell specification

Summary Muscle and brain pigment cell specification was studied by disrupting cell adhesion, cell dissociation, and reaggregation in embryos of the ascidianStyela clava. Treatment of embryos with Ca²⁺-free sea water between the 2-cell and gastrula stages disrupted blastomere adhesion but did not prevent acetylcholinesterase or muscle actin expression in presumptive muscle cells. Similar treatments initiated between the 2- and 32-cell stages caused more ectoderm cells to express tyrosinase and develop pigment granules than expected from the cell lineage. Whereas 2 pigment cells become the otolith and ocellus sensory organs in normal embryos, up to 33 pigment cells could differentiate in embryos after disruption of cell adhesion. Replacement of Ca²⁺-free sea water with normal sea water restored cell adhesion and usually resulted in development of embryos containing the conventional number of pigment cells. Dissociation of embryos into single cells between the 2- and 64-cell stages and culture of these cells beyond the fate restricted stage had no effect on the accumulation of muscle actin mRNA and muscle actin synthesis, but blocked pigment cell differentiation. Reaggregation of the dissociated cells did not enhance the number of cells that developed muscle features, but rescued pigment cell development. The results indicate that ascidian muscle cell specification occurs by an autonomous mechanism, whereas pigment cell specification occurs by a conditional mechanism involving cell interactions. In addition, the results suggest that negative cell interactions may restrict the potential for pigment cell development in the ectoderm of cleaving ascidian embryos.     

The development of melanosomes in the pigment epithelium of the chick embryo

Summary The origin of the melanosome in the pigment epithelium of the chick embryo was studied by electron microscopy and cytochemistry of tyrosinase. The melanosome appears first at stage 16 in the dorso-caudal region of the optic cup and the first appearance of the tyrosinase activity can also be detected at the same stage in Golgi sac. At the early stages, premelanosomes and amorphous, electron dense granules which are considered to be the developing premelanosomes appear as a group at the basal region of the outer layer cell. The membrane of these granules is connected with that of ER. Attention should be paid to the fact that there are tyrosinase-negative premelanosomes, even when Golgi sac and Golgi vesicles are tyrosinase-positive. According to these facts it can be said that the site of origin of premelanosomes are not Golgi vesicles, but the smooth-surfaced ER connected with the rough-surfaced ER, and that the tyrosinase is transported to premelanosomes by tyrosinase-containing vesicles which originate from matured Golgi sac.The author is grateful to Prof. Dr. Junnosuke Nakai for his encouragement and valuable suggestions. Thanks are also due to Prof. Dr. Eichi Yamada and Prof. Dr. Shiro Igarashi for their comments on the electron-microscopic study.     

Zinc deficiency leads to lipofuscin accumulation in the retinal pigment epithelium of pigmented rats

Background

Age-related macular degeneration (AMD) is associated with lipofuscin accumulation whereas the content of melanosomes decreases. Melanosomes are the main storage of zinc in the pigmented tissues. Since the elderly population, as the most affected group for AMD, is prone to zinc deficit, we investigated the chemical and ultrastructural effects of zinc deficiency in pigmented rat eyes after a six-month zinc penury diet.

Methodology/Principal Findings

Adult Long Evans (LE) rats were investigated. The control animals were fed with a normal alimentation whereas the zinc-deficiency rats (ZD-LE) were fed with a zinc deficient diet for six months. Quantitative Energy Dispersive X-ray (EDX) microanalysis yielded the zinc mole fractions of melanosomes in the retinal pigment epithelium (RPE). The lateral resolution of the analysis was 100 nm. The zinc mole fractions of melanosomes were significantly smaller in the RPE of ZD-LE rats as compared to the LE control rats. Light, fluorescence and electron microscopy, as well as immunohistochemistry were performed. The numbers of lipofuscin granules in the RPE and of infiltrated cells (Ø>3 µm) found in the choroid were quantified. The number of lipofuscin granules significantly increased in ZD-LE as compared to control rats. Infiltrated cells bigger than 3 µm were only detected in the choroid of ZD-LE animals. Moreover, the thickness of the Bruch''s membrane of ZD-LE rats varied between 0.4–3 µm and thin, rangy ED1 positive macrophages were found attached at these sites of Bruch''s membrane or even inside it.

Conclusions/Significance

In pigmented rats, zinc deficiency yielded an accumulation of lipofuscin in the RPE and of large pigmented macrophages in the choroids as well as the appearance of thin, rangy macrophages at Bruch''s membrane. Moreover, we showed that a zinc diet reduced the zinc mole fraction of melanosomes in the RPE and modulated the thickness of the Bruch''s membrane.     

Notch signaling in the pigmented epithelium of the anterior eye segment promotes ciliary body development at the expense of iris formation

The ciliary body and iris are pigmented epithelial structures in the anterior eye segment that function to maintain correct intra‐ocular pressure and regulate exposure of the internal eye structures to light, respectively. The cellular and molecular factors that mediate the development of the ciliary body and iris from the ocular pigmented epithelium remain to be fully elucidated. Here, we have investigated the role of Notch signaling during the development of the anterior pigmented epithelium by using genetic loss‐ and gain‐of‐function approaches. Loss of canonical Notch signaling results in normal iris development but absence of the ciliary body. This causes progressive hypotony and over time leads to phthisis bulbi, a condition characterized by shrinkage of the eye and loss of structure/function. Conversely, Notch gain‐of‐function results in aniridia and profound ciliary body hyperplasia, which causes ocular hypertension and glaucoma‐like disease. Collectively, these data indicate that Notch signaling promotes ciliary body development at the expense of iris formation and reveals novel animal models of human ocular pathologies.     

Regulation of vertebrate eye development by Rx genes

The paired-like homeobox-containing gene Rx has a critical role in the eye development of several vertebrate species including Xenopus, mouse, chicken, medaka, zebrafish and human. Rx is initially expressed in the anterior neural region of developing embryos, and later in the retina and ventral hypothalamus. Abnormal regulation or function of Rx results in severe abnormalities of eye formation. Overexpression of Rx in Xenopus and zebrafish embryos leads to overproliferation of retinal cells. A targeted elimination of Rx in mice results in a lack of eye formation. Mutations in Rx genes are the cause of the mouse mutation eyeless (ey1), the medaka temperature sensitive mutation eyeless (el) and the zebrafish mutation chokh. In humans, mutations in Rx lead to anophthalmia. All of these studies indicate that Rx genes are key factors in vertebrate eye formation. Because these results cannot be easily reconciled with the most popular dogmas of the field, we offer our interpretation of eye development and evolution.     

Indian hedgehog signaling from endothelial cells is required for sclera and retinal pigment epithelium development in the mouse eye

The development of extraocular orbital structures, in particular the choroid and sclera, is regulated by a complex series of interactions between neuroectoderm, neural crest and mesoderm derivatives, although in many instances the signals that mediate these interactions are not known. In this study we have investigated the function of Indian hedgehog (Ihh) in the developing mammalian eye. We show that Ihh is expressed in a population of non-pigmented cells located in the developing choroid adjacent to the RPE. The analysis of Hh mutant mice demonstrates that the RPE and developing scleral mesenchyme are direct targets of Ihh signaling and that Ihh is required for the normal pigmentation pattern of the RPE and the condensation of mesenchymal cells to form the sclera. Our findings also indicate that Ihh signals indirectly to promote proliferation and photoreceptor specification in the neural retina. This study identifies Ihh as a novel choroid-derived signal that regulates RPE, sclera and neural retina development.