The lens organizes the anterior segment: specification of neural crest cell differentiation in the avian eye

During the development of the anterior segment of the eye, neural crest mesenchyme cells migrate between the lens and the corneal epithelium. These cells contribute to the structures lining the anterior chamber: the corneal endothelium and stroma, iris stroma, and trabecular meshwork. In the present study, removal of the lens or replacement of the lens with a cellulose bead led to the formation a disorganized aggregate of mesenchymal cells beneath the corneal epithelium. No recognizable corneal endothelium, corneal stroma, iris stroma, or anterior chamber was found in these eyes. When the lens was replaced immediately after removal, a disorganized mass of mesenchymal cells again formed beneath the corneal epithelium. However, 2 days after surgery, the corneal endothelium and the anterior chamber formed adjacent to the lens. When the lens was removed and replaced such that only a portion of its anterior epithelial cells faced the cornea, mesenchyme cells adjacent to the lens epithelium differentiated into corneal endothelium. Mesenchyme cells adjacent to lens fibers did not form an endothelial layer. The cell adhesion molecule, N-cadherin, is expressed by corneal endothelial cells. When the lens was removed the mesenchyme cells that accumulated beneath the corneal epithelium did not express N-cadherin. Replacement of the lens immediately after removal led to the formation of an endothelial layer that expressed N-cadherin. Implantation of lens epithelia from older embryos showed that the lens epithelium maintained the ability to support the expression of N-cadherin and the formation of the corneal endothelium until E15. This ability was lost by E18. These studies provide evidence that N-cadherin expression and the formation of the corneal endothelium are regulated by signals from the lens. N-cadherin may be important for the mesenchymal-to-epithelial transformation that accompanies the formation of the corneal endothelium.     

Corneal morphogenesis in the Indian garden lizard,Calotes versicolor (agamidae)

The present study traces corneal morphogenesis in a reptile, the lizard Calotes versicolor, from the lens placode stage (stage 24) until hatching (stage 42), and in the adult. The corneal epithelium separates from the lens placode as a double layer of peridermal and basal cells and remains bilayered throughout development and in the adult. Between stages 32– and 33+, the corneal epithelium is apposed to the lens, and limbic mesodermal cells migrate between the basement membrane of the epithelium and the lens capsule to form a monolayered corneal endothelium. Soon thereafter a matrix of amorphous ground substance and fine collagen fibrils, the presumptive stroma, is seen between the epithelium and the endothelium. Just before stage 34 a new set of limbic mesodermal cells, the keratocytes, migrate into the presumptive stroma. Migrating limbic mesodermal cells, both endothelial cells and keratocytes, use the basement membrane of the epithelium as substratum. Keratocytes may form up to six cell layers at stage 37, but in the adult stroma they form only one or two cell layers. The keratocytes sysnthesize collagen, which aggregates as fibrils and fibers organized in lamellae. The lamellae become condensed as dense collagen layers subepithelially or become compactly organized into a feltwork structure in the rest of the stroma. The basement membrane of the endothelium is always thin. Thickness of the entire cornea increases up to stage 38 and decreases thereafter until stage 41. In the adult the cornea is again nearly as thick as at stage 38.     

Immunofluorescent localization of collagen types I, II, and III in the embryonic chick eye.

The appearance and distribution of type I, II, and III collagens in the developing chick eye were studied by specific antibodies and indirect immunofluorescence. At stage 19, only type I collagen was detected in the primary corneal stroma, in the vitreous body, and along the lens surface. At later stages, type I collagen was located in the primary and secondary corneal stroma and in the fibrous sclera, but not around the lens. Type II collagen was first observed at stage 20 in the primary corneal stroma, neural retina, and vitreous body. It was particularly prominent at the interface of the neural retina and vitreous body and, from stage 30 on, in the cartilaginous sclera. The primary corneal stroma consisted of a mixture of type I and II collagens between stages 20 and 27. Invasion of the primary corneal stroma by mesenchyme and subsequent deposition of fibroblast-derived collagen corresponded with a pronounced increase of type I collagen, throughout the entire stroma, and of type II collagen, in the subepithelial region. Type II collagen was also found in Bowman's and Descemet's membranes. A transient appearance of type III collagen was observed in the corneal epithelial cells, but not in the stroma (stages 20–30). The fully developed cornea contained both type I and II collagens, but no type III collagen. Type III collagen was prominent in the fibrous sclera, iris, nictitating membrane, and eyelids.     

Fibronectin in the development of embryonic chick eye.

The time course of appearance and distribution of fibronectin in the developing eye have been studied in chick embryos by indirect immunofluorescence. At the 12-somite stage, fibronectin was detected as a layer under the ectodermal cells overlying the forebrain vesicle; it was also present in the head mesenchyme. During formation of the lens placode and its invagination, a zone containing fibronectin persisted around the lens as a component of the capsule. The fibronectin-containing layer was separated from the corneal epithelial cells during the formation of the acellular stroma. The migrating corneal endothelial cells were seen posterior to the fibronectin layer. The secondary stroma was strongly positive for fibronectin. Fibronectin disappeared from the cornea starting from its posterior part along with the corneal condensation. In the newborn chicken cornea, fibronectin was present only in Descemet's membrane. In addition, the embryonic vitreous body had a network of fibronectin-containing material. The distribution of fibronectin in the developing cornea, as well as other data available on this glycoprotein, is consistent with the proposed role of fibronectin in positioning and migration of cells and in organization of the extracellular matrix.     

Analysis of corneal development with monoclonal antibodies. I. Differentiation in isolated corneas

Monoclonal antibodies highly selective for developmentally regulated antigens present in the cornea (Zak and Linsenmayer, Dev. Biol. 99, 373-381, 1983) have been used to immunohistochemically evaluate differentiation in intact chick corneas cultured on the chorioallantoic membrane (CAM) of host embryos. One antibody is directed against the epithelial cell layer and the other is against the corneal stromal matrix. It has been established that both antigens recognized by the antibodies are expressed de novo in young explanted corneas and that the stromal matrix antigen is a product of the corneal fibroblasts. Thus expression of the antigens can be used as criteria for overt differentiation of the respective cell types. The antibodies have been employed to assess when the corneal epithelial and stromal cells become capable of autonomous differentiation within isolated corneas. To accomplish this, corneas of various ages were explanted with and without adjacent pericorneal tissues. The results indicate that, under the culture conditions employed, corneal stromal differentiation is dependent on the presence of the lens until stage 28 (51/2-6 days of development), which is the time when invasion of the stroma by pericorneal mesenchymal cells is initiated. After stage 28, the stromal matrix antigen was expressed by isolated corneas irrespective of the presence of the lens. Possibly the lens acts by maintaining the integrity of the corneal endothelial monolayer and thus promoting normal migration of pericorneal mesenchymal cells into the primary corneal stroma, where they undergo differentiation. Conversely, differentiation of the corneal epithelium was independent of any pericorneal structure from the earliest stage examined (41/2-5 days of development). It was even independent of overt stromal differentiation, thus suggesting an early and strong determination for this tissue.     

Scanning electron microscopic study of cell movements in the corneal endothelium of the avian embryo

Using the scanning electron microscope we have examined the appearance, in situ, of the migrating cells of the presumptive corneal endothelium in the chick embryo. The primary stroma, a collagenous layer which serves as a major substrate for the migration of the cells, was found to have many deep folds and ridges. The collagen fibrils of the stroma, as seen on its posterior surface, appear arranged more or less isotropically. Areas of orthogonal packing are small and relatively sparse. While the cells make contact with this substratum they do not seem to be guided by its topographic features. The migrating endothelial cells lack well developed ruffles, supporting the increasing prevalent idea that the pattern of cell surface activity observed in vitro during cellular locomotion, is not an absolute prerequisite for cell movement.     

Formation of corneal endothelium is essential for anterior segment development - a transgenic mouse model of anterior segment dysgenesis

The anterior segment of the vertebrate eye is constructed by proper spatial development of cells derived from the surface ectoderm, which become corneal epithelium and lens, neuroectoderm (posterior iris and ciliary body) and cranial neural crest (corneal stroma, corneal endothelium and anterior iris). Although coordinated interactions between these different cell types are presumed to be essential for proper spatial positioning and differentiation, the requisite intercellular signals remain undefined. We have generated transgenic mice that express either transforming growth factor (alpha) (TGF(alpha)) or epidermal growth factor (EGF) in the ocular lens using the mouse (alpha)A-crystallin promoter. Expression of either growth factor alters the normal developmental fate of the innermost corneal mesenchymal cells so that these cells often fail to differentiate into corneal endothelial cells. Both sets of transgenic mice subsequently manifest multiple anterior segment defects, including attachment of the iris and lens to the cornea, a reduction in the thickness of the corneal epithelium, corneal opacity, and modest disorganization in the corneal stroma. Our data suggest that formation of a corneal endothelium during early ocular morphogenesis is required to prevent attachment of the lens and iris to the corneal stroma, therefore permitting the normal formation of the anterior segment.     

Corneal stem cells and tissue engineering: Current advances and future perspectives

Major advances are currently being made in regenerative medicine for cornea. Stem cell-based therapies represent a novel strategy that may substitute conventional corneal transplantation, albeit there are many challenges ahead given the singularities of each cellular layer of the cornea. This review recapitulates the current data on corneal epithelial stem cells, corneal stromal stem cells and corneal endothelial cell progenitors. Corneal limbal autografts containing epithelial stem cells have been transplanted in humans for more than 20 years with great successful rates, and researchers now focus on ex vivo cultures and other cell lineages to transplant to the ocular surface. A small population of cells in the corneal endothelium was recently reported to have self-renewal capacity, although they do not proliferate in vivo. Two main obstacles have hindered endothelial cell transplantation to date: culture protocols and cell delivery methods to the posterior cornea in vivo. Human corneal stromal stem cells have been identified shortly after the recognition of precursors of endothelial cells. Stromal stem cells may have the potential to provide a direct cell-based therapeutic approach when injected to corneal scars. Furthermore, they exhibit the ability to deposit organized connective tissue in vitro and may be useful in corneal stroma engineering in the future. Recent advances and future perspectives in the field are discussed.     

Tenascin Mr 220,000 isoform expression correlates with corneal cell migration.

The three isoforms of chicken tenascin, an extracellular matrix glycoprotein, are generated by alternatively spliced fibronectin type III domains. The resulting proteins migrate as bands of Mr 220,000 (ten220), Mr 200,000 (ten200) and Mr 190,000 (ten190) on SDS-PAGE. We describe here two monoclonal antibodies, one specific for ten220 (mAb T17) and another that recognizes all isoforms (mAb T16). These were used to examine the differential expression of isoforms during development. Most impressive is the close correlation between ten220 expression and cell migration in the embryonic cornea. Initially (stage 18), ten190/200 can be detected within the corneal epithelium and along the basement membranes of the lens and sclera. Ten220 appears within the primary stroma immediately prior to the invasion by neural-crest-derived cells. This expression is maintained during the subsequent migration of fibroblasts from the conjunctiva into the primary stroma. With the completion of migration and the marked increase in matrix synthesis by corneal fibroblasts, ten220 disappears. Ten190/200 remains in the region adjoining the endothelium, the Bowman's membrane and the adjacent stroma. The cell-migration-associated isoform is isolated from extracts of embryonic tissues as a homohexamer. Low molecular weight forms appeared absent but a new tenascin band of Mr 210,000 could be detected in brain extracts which may be a new isoform. We conclude that the synthesis of tenascin isoforms is under tight developmental control and speculate that a function of the additional domains is to facilitate cell migration.     

Secretion of collagen types I and II by epithelial and endothelial cells in the developing chick cornea demonstrated by in situ hybridization and immunohistochemistry

Cells involved in the synthesis of collagen types I and II in the cornea of developing chick embryos have been studied by using in situ hybridization and immunohistochemistry. Corneas processed for in situ hybridization with the type I and II collagen probes demonstrated specific mRNAs in the epithelium of embryos at stage 18 with an increase at stages between 26 and 31, and then gradual decrease to the background level in the next several days. In the endothelium, a small amount of specific mRNA was recognized through these stages. In the stroma, only sections hybridized with the type I probe demonstrated mRNA in fibroblasts. Immunostaining demonstrated specific collagen types in the stroma at sites which were closely associated with cells containing specific mRNAs. Both collagens type I and II were present beneath the epithelium as narrow bands at stage 18; as the thicker primary stroma at stages 20 and 26; and as subepithelial, subendothelial and stromal staining at stage 31. Thereafter, type I collagen was increased in the stroma but it was also noted in the subepithelial and, to a lesser degree, subendothelial regions, whereas type II collagen was gradually confined to the subendothelial matrix. Electron microscopic examination of sections from 5-day-old (stage-27) embryo corneas using antibodies against the carboxyl propeptides of type I and II procollagens revealed the presence of these procollagens within the cisternae of the endoplasmic reticulum and Golgi vesicles in both epithelial and endothelial cells. In the epithelial cells both the periderm and basal cells contained these procollagens within the cytoplasmic organelles. These results indicate that not only the epithelial cells, but also the endothelial cells secrete collagen types I and II during the formation of the primary corneal stroma and for several days after invasion of fibroblasts.     

Macrophages of hemangioblastic lineage invade the lens vesicle-ectoderm interspace during closure and detachment of the avian embryonic lens

Summary An area of cell death is apparent in the lens vesicle margin and the lens stalk during closure and detachment of the lens anlage from the cephalic ectoderm. Free phagocytic cells closely associated with this area of cell death have been interpreted as cells migrating from the lens epithelium. Scanning and transmission electron microscopy, light-microscopic histochemical staining for acid phosphatase and immunostaining using MB1 (a monoclonal antibody specific for quail endothelial and hemopoietic cells) of chimeras of chick embryo and quail yolk sac were used to analyze these lens vesicle-associated free phagocytic cells. The cells have morphological features identical to those of macrophages in other embryonic tissues. In contrast to epithelial cells phagocytosing cell debris, they exhibit strong acid phosphatase activity, a feature typical of macrophages. In addition, free phagocytic cells are MB1 positive in chick embryo-quail yolk sac chimeras, hence they proceed from cells of hemangioblastic lineage originating in the yolk sac. These results indicate that the lens vesicle-associated free phagocytic cells are macrophages. Observations of MB1 positive amoeboid cells in the juxta-retinal mesenchyme and on the borders of the optic cup suggest that these macrophages migrate through the mesenchyme surrounding the eye primordium. Macrophages are seen in both the interspace between lens vesicle and ectoderm and in the lumen of the lens as well as within both the ectoderm and the lens epithelium. In these locations they remove cell debris, and thereby contribute to the complete disappearance of the area of cell death. Macrophages remain in the lens vesicle-ectoderm interspace until developmental stages at which it is invaded by corneal endothelial cells.     

Use of 6-diazo-5-oxo-l-norleucine to study interaction between myocardial glycoconjugate secretion and endothelial activation in the early embryonic chick heart

The glutamine analog, 6-diazo-5-oxo-l-norleucine (DON), a glycoconjugate inhibitor, was used to probe the relationships between myocardial secretion of extracellular matrix and endothelial differentiation and formation of cushion mesenchyme (primordia of AV values). When DON was given to stage 12 chick embryos maintained in shell-less culture, the myocardial secretion gradient of glucose- and sulfate-labeled matrix was blocked. Concomitantly, the endothelium failed to complete activation but continued to divide and incorporate thymidine. By varying DON concentration, two distinct phases of endothelial differentiation were identified: the first (labile to 0.5 μg) involved hypertrophy, the second (labile to 0.25 μg) acquisition of migratory appendages with resultant mesenchyme formation. Glucosamine + DON (but not inosine, glucose, or glutamine) restored the matrical secretion gradient and to varying degrees both phases of endothelial activation. Endothelia totally suppressed from forming mesenchyme in situ acquired this capacity when explanted into three-dimensional collagen gel culture. The capacity was enhanced by glucosamine given in situ as an inhibitory override, dependent upon serum concentration, inhibited by heat-inactivated serum or by adding DON to the medium, but unaffected by hyaluronate. These results were compared to those obtained by co-culturing endothelium and myocardium and discussed in terms of the hypothesis that cushion mesenchyme formation results from an epithelial interaction mediated by glycoconjugates.     

Corneal development. IV. Interruption of collagen excretion into the primary stroma of the cornea with L-azetidine-2-carboxylic acid

The primary stroma of the cornea of the chick embryo contains a cell-free orthogonal ply of collagen fibrils which is delineated clearly by Gomori's silver stain for reticulin and has, in miniature, the same fibrous architecture as the mature stroma. The collagen of this matrix is synthesized by the basal cells of the corneal epithelium and deposited beneath them a layer at a time.     

Control of corneal differentiation by extracellular materials. Collagen as a promoter and stabilizer of epithelial stroma production

The primary stroma of the cornea of the chick embryo consists of orthogonally arranged collagen fibrils embedded in glycosaminoglycan (GAG) produced by the epithelium under the early inductive influence of the lens. The experiments reported here were designed to test whether or not the collagen of the lens basement lamina is capable of stimulating corneal epithelium to produce primary stroma. Enzymatically isolated 5-day-old corneal epithelia were grown for 24 hr in vitro in the presence of ³⁵SO₄ or proline-³H on various substrata. Epithelia cultured on lens capsule synthesized 2.5 times as much GAG (as measured by incorporation of label into CPC precipitable material) and almost 3 times as much collagen (assayed by hot TCA extraction or collagenase sensitivity) as when cultured on Millipore filter or other noncollagenous substrata. A similar stimulatory response was observed when epithelium was combined with chemically pure chondrosarcoma collagen, NaOH-extracted lens capsule, vitreous humor, frozen-killed corneal stroma or cartilage, or tendon collagen gels; in the latter case, the magnitude of the effect can be shown to be related to concentration of the collagen in the gel. All of the collagenous substrata stimulate not only extracellular matrix production, but also polymerization of corneal-type matrix, as judged by ultrastructural criteria and by the association of more radioactivity with the tissue than the medium. Since purified chondrosarcoma collagen is as effective as lens capsule, the stimulatory effect on collagen and GAG synthesis by corneal epithelium is not specific for basal lamina (lens capsule) collagen.     

STUDIES ON THE CORNEA : II. The Uptake and Transport of Colloidal Particles by the Living Rabbit Cornea in Vitro

In vitro studies of the transport of colloidal particles by the cornea were carried out on intact corneas of adult rabbits in a chamber described by Donn, Maurice, and Mills (2) in which the epithelial or the endothelial surface of the cornea was exposed to thorium dioxide or saccharated iron oxide under various conditions. These studies confirmed the results of previous work in vivo and allowed modification of the experimental conditions. Particles are pinocytosed at the apical surface of the corneal endothelium and carried around the terminal bar in membrane-bounded vesicles. Basal to the terminal bar these vesicles fuse with the lateral cell margin and their contents are released into the intercellular space, in which they appear to be carried by a one-way flow down to Descemet's membrane and the corneal stroma. Indications that the endothelial transport is an active process are presented by the different pathways of transport into or out of the corneal stroma, as well as by the approximately 70 per cent reduction in transport activity at low temperatures.     

Endothelial Progenitors Exist within the Kidney and Lung Mesenchyme

The renal endothelium has been debated as arising from resident hemangioblast precursors that transdifferentiate from the nephrogenic mesenchyme (vasculogenesis) and/or from invading vessels (angiogenesis). While the Foxd1-positive renal cortical stroma has been shown to differentiate into cells that support the vasculature in the kidney (including vascular smooth muscle and pericytes) it has not been considered as a source of endothelial cell progenitors. In addition, it is unclear if Foxd1-positive mesenchymal cells in other organs such as the lung have the potential to form endothelium. This study examines the potential for Foxd1-positive cells of the kidney and lung to give rise to endothelial progenitors. We utilized immunofluorescence (IF) and fluorescence-activated cell sorting (FACS) to co-label Foxd1-expressing cells (including permanently lineage-tagged cells) with endothelial markers in embryonic and postnatal mice. We also cultured FACsorted Foxd1-positive cells, performed in vitro endothelial cell tubulogenesis assays and examined for endocytosis of acetylated low-density lipoprotein (Ac-LDL), a functional assay for endothelial cells. Immunofluorescence and FACS revealed that a subset of Foxd1-positive cells from kidney and lung co-expressed endothelial cell markers throughout embryogenesis. In vitro, cultured embryonic Foxd1-positive cells were able to differentiate into tubular networks that expressed endothelial cell markers and were able to endocytose Ac-LDL. IF and FACS in both the kidney and lung revealed that lineage-tagged Foxd1-positive cells gave rise to a significant portion of the endothelium in postnatal mice. In the kidney, the stromal-derived cells gave rise to a portion of the peritubular capillary endothelium, but not of the glomerular or large vessel endothelium. These findings reveal the heterogeneity of endothelial cell lineages; moreover, Foxd1-positive mesenchymal cells of the developing kidney and lung are a source of endothelial progenitors that are likely critical to patterning the vasculature.     

Synthesis of sulfated glycosaminoglycans by embryonic corneal epithelium

The primary corneal stroma is produced by the overlying epithelium. The endothelium appears between 4 and 5 days, fibroblasts at 6 days, and at 12 days the epithelium stratifies. We investigated the synthesis of glycosaminoglycan (GAG) by the epithelium during this developmentally significant period. The sulfated GAG synthesized by isolated 4–6-day-old corneal epithelia during the first 24 hr in vitro are entirely accountable for as chondroitin sulfates and heparan sulfates. Nearly 50% of the total sulfated GAG synthesized by epithelia on Millipore filters is lost to the medium, but only 30–40% is lost when frozen killed lens capsule or stroma is the substratum. Retention of isotope by the tissue is correlated with visible matrix polymerization. The relative amount of heparan sulfate synthesized by the developing epithelium 24 hr in vitro decreases from about 50% of the total sulfated GAG for 4-day-old epithelium to 12% for 12-day-old epithelium. A similar decrease in heparan sulfate synthesis occurs with time in culture. The relative amount of GAG identified as chondroitin sulfate and heparan sulfate is the same when ³H-glucosamine is used to label GAG as when ³⁵SO₄ is used. We conclude that the corneal epithelium produces only sulfated polysaccharides. Since hyaluronate is synthesized by whole 5-day-old corneas, it must be the product of the endothelium.