Differentiation of lens in cultures of neural retinal cells of chick embryos

When dissociated cells of neural retinae of 8-day-old chick embryos were cultured, monolayer sheets of epithelial cells were obtained. These cells proliferated actively. After about 30 days of culture, both lentoid bodies and pigment cells were differentiated in all plates. In the second and the third generation cultures, both differentiations were also observed. Lentoid bodies showed positive immunofluorescence for fluorescein-isothiocyanate-conjugated antiserum against δ-crystallin. Molecular constituents of lentoid bodies were very similar to those of lenses developing in situ, as revealed by immunodiffusion tests. Several lines of evidence for the “neural retinal” origin of lentoid bodies, as opposed to their being derived from lens cells inadvertently included in the original culture inocula are given. Some implications of the present results for the problem of “determination” are discussed.     

Differentiation of lens and pigment cells in cultures of neural retinal cells of early chick embryos

Dissociated cells of neural retinas of 3.5-day-old chick embryos (stages 20–21) were cultured as a monolayer in order to examine their differentiation in vitro. These cells started to grow actively soon after inoculation and formed a confluent sheet within which neuroblast-like cells with long cytoplasmic processes were differentiated by 8 days. At about 16 days the differentiation of both lentoid bodies and foci of pigment cells was observed, while neuronal structure disappeared. The numbers of lentoid bodies and foci of pigmented cells continued to increase up to 30 days, when primary cultures were terminated. The increase in δ-crystallin content, as measured by quantitative immunoelectrophoresis assay using rabbit antiserum against δ-crystallin, was consistent with the increase in the number of lentoid bodies in cultures. The amount of α-crystallin per culture, estimated by the same technique as above, reached a maximum at 16 days and decreased slightly during further culture. The differentiation of both lentoid bodies and pigment cells was observed also in cultures of the second generation. The results demonstrate that cells of the undifferentiated neuroepithelium of 3.5-day-old embryonic retinas can achieve at least three differentiations, neuronal, lens, and pigment cells, in vitro. We discuss several differences between the present results and the previous ones from in vitro cultures of 8- to 9-day-old embryonic neural retinas.     

A DEMONSTRATION OF LENS FORMING-CELLS IN NEURAL RETINA IN CLONAL CELL CULTURE

Clonal cultures with 1,000–3,000 cells were prepared from cells harvested from high density cultures of neural retina of 8-day-old chick embryos. About 1.14% and 0.31% of inoculated cells developed into recogniziable colonies in Eagle's MEM and in Ham's F-12 supplemented with fetal calf serum respectively. Of these colonies, lentoid bodies of authentic lens nature were differentiated in 10% and 33.52% in MEM and F-12 respectively. Cells harvested from high density cultures of the anterior and posterior portions of the neural retina were clonally cultured. Plating efficiency was much higher in the anterior cells than in the posterior ones and clonies with lentoid differentiation were developed only in clonal cultures of the anterior cells.     

Transdifferentiation of "lentoid" structures in cultures derived from pigmented epithelium was inhibited by collagen.

Cells from pigmented retina of 8- to 9-day-old chick embryos were cultured under two different conditions: on noncoated (NS) or collagen-coated (CS) substrates. Although cells on CS seemed to start dividing 2 to 3 days earlier than those on NS, their early growth rates were basically similar. Cells on CS stopped growing after attaining confluency and formed a monolayer, while cells on NS continued to grow after confluency and overlapped each other. In early growth phase, cells on both substrates became depigmented. Cells became repigmented earlier on CS than on NS. The average melanin content of cells in confluent cultures on CS was two to three times higher than that of cells on NS. By Day 30 “lentoid bodies” were formed only in cultures on NS. Immunoelectrophoretic tests showed the presence of all crystallins (α-, β-, and δ) in cultures on NS but not in cultures on CS. It is concluded that a collagen substrate inhibits “transdifferentiation” of pigmented retinal cells into lens during cell culture.     

Enhancement of differentiation of lens and pigment cells by ascorbic acid in cultures of neural retinal cells of chick embryos.

When dissociated cells of neural retinae of 9-day-old chick embryos were cultured in Eagle's minimum essential medium supplemented with dialyzed fetal calf serum, both the proliferation and differentiation of the neural retinal cells were inhibited. These cells remained quiescent and flattened. When ascorbic acid was added to such a medium, the cells started to grow and differentiated into lentoid bodies and pigmented cells after about 10 days.     

Differentiation of Lens and Pigment Cells in Cultures of Brain Cells of Chick Embryos

Dissociated cells of brains (tel- and diencephalons) of 3.5-day-old chick embryos were cultivated in vitro under the cell culture conditions which are known to be permissive for neural retinal cells (NR cells) to transdifferentiate into lens and/or pigmented epithelial cells (PE cells). The differentiation of lentoid bodies (LBs) with lens-specific (δ-crystallin and PE cells with melanin granules was observed in such brain cultures.
LBs appeared in two different phases, i. e., 2–3 days and 16–30 days of cultivation, and after 40 days of culture these structures were formed in all 60 culture dishes. Sometimes, LBs were observed in foci of PE cells formed during earlier stages of brain cultures. When similar brain cultures were prepared with older embryos of 5-, 8.5-, 14-, and 16-days of incubation, no differentiation of lens and PE cells was observed.     

Can Once Neuronally Differentiated Cells of Neural Retina Be Lentoidogenic in Cell Culture?*

Cells dissociated from neural retina of 3.5-day-old chick embryos transdifferentiated extensively into lens cells under the conditions of a cell culture for 3 to 4 weeks. In early satges of cell culture by about 10 days, cultures consisted of small round cells often with cytoplasmic processes(N-cells) and flattened epithelial cells (E-cells). Only N-cells were stained with a fluorescent dye Merocyanine 540. When cells harvested from early cultures were separated into two fractions by centrifugation in Percoll gradient, the specific activity of choline acetyltransferase was much higher in the fraction consisting mainly of N-cells than in other fraction mainly of E-cells. Continuous daily observations as well as cinematographic observations of living cultures indicate that lentoid bodies were often formed in the locations where clusters of N-cells had been found in early stages of culturing. The possibility of transdifferentiation of N-cell clusters into lentoid bodies is discussed.     

Crystallin synthesis in lens differentiation in cultures of neural retinal cells of chick embryos.

Dissociated cells of neural retinas of 3.5-day-old chick embryos differentiated into “lentoid bodies” within about 10–12 days when cultured in vitro. Protein synthesis of these cultured cells was studied with the use of SDS-polyacrylamide gel electrophoresis, affinity chromatography, and autoradiography combined with immunological techniques. Incorporation of [¹⁴C]leucine into total proteins, α-crystallin, and δ-crystallin was estimated after increasing times of culture up to about 30 days. Isotope incorporation into δ-crystallin was detected at 9 days, and it increased sevenfold after another 17 days. α-Crystallin was also first detected at 9 days, but its relative content reached a maximum at 12 days and then decreased gradually. The ratio of δ-crystallin synthesis to total protein synthesis increased up to 40% at 26 days, while that of α-crystallin synthesis remained 3% throughout the culture period. These results show that lens differentiation from neural retinal cells is associated with the preferential synthesis of lens crystallins, particularly of δ-crystallin.     

EFFECTS OF CULTURE MEDIA ON THE "FOREIGN" DIFFERENTIATION OF LENS AND PIGMENT CELLS FROM NEURAL RETINA IN VITRO

Neural retinal cells of 3.5-day-old quail embryos were cultured as a monolayer to examine their potentials for differentiation in vitro. The "foreign" differentiation into lentoid and pigment cells was much affected by the choice of medium (Eagle's MEM and Ham's F–12); in Eagle's MEM, neural retinal cells differentiated extensively into lentoid bodies and pigment cells, as previously reported in cultures of chick neural retinal cells, while in Ham's F–12, though the cells proliferated as well as in Eagle's MEM, the "foreign" differentiation is inhibited. When primary cultures were transferred to secondary cultures, the occurrence of "foreign" differentiation did not depend on the medium used for the primary culturing, but wholly on the medium used for secondary cultures. This difference in differentiation in two different media was quantitatively substantiated by measuring the amounts of α-, δ-crystallins and melanins of cultured cells.     

Biochemical and immunological studies of lentoid formation in cultures of embryonic chick neural retina and day-old chick lens epithelium

During long-term cell culture of 8-day embryonic chick neural retina, lentoid bodies containing lens crystallins are developed. Although very low levels of crystallin can be detected in the embryonic neural retina, gross synthesis of each major crystallin class (α, anodal β, cathodal β, and δ) begins only after 12–16 days in culture. This occurs at least 10 days before lentoid bodies can be distinguished by eye. The concentration of each crystallin class was determined during lentoid development in cultures of both neural retina and lens epithelium. The proportions of crystallins in lentoid-containing cultures do not resemble those of embryonic lens fibres. Comparisons between two chick strains (N and Hy-1) differing in their growth rates revealed several differences in the crystallin compositions of lentoid bodies. These differences imply independent quantitative regulation for most or all of the crystallins.     

The possibility of lens formation in explants of the retina and pigment epithelium of the eye in chick embryos

Undissociated tissue explants of the retina and retinal pigment epithelium (RPE) of 3,5-, 4-, 5- and 8-day-old chick embryos were cultured in vitro. After 7 days in culture, lentoids were observed in explants of either retina or RPE from 3,5-, 4- and 5-day-old embryos. As demonstrated by immunohistochemistry, these lentoids contained specific chick lens proteins (alpha-, beta- and delta-crystallins). No crystallin-containing cells were found in eye tissue explants from 8-day-old embryos. However, when 5-bromo-deoxyuridine (25 microM) was introduced into the medium at the beginning of culturing (for 12 h), large eosinophilic cells containing alpha-, beta- and delta-crystallins were detected in retinal explants of the 8-day old embryos. Thus, retina and RPE of 3,5-5-day-old chick embryos are capable of lens differentiation after explantation in vitro without dissociation into individual cells. This capacity is lost during development.     

A decay of gap junctions in association with cell differentiation of neural retina in chick embryonic development.

Ultrastructural studies of thin-sectioned and freeze-cleaved materials were performed on developing retinal tissues of 3- to 9-day-old chick embryos to clarify the junctional structures between neural retinal cells and between neural retinal cells and cells of the pigmented epithelium. Frequency, size and position of gap junctions in developing neural retina are different at each stage of development. In 3-day-old embryos, some cells adhere to each other by gap junctions immediately below the outer limiting membrane of neural retinae. The size and number of gap junctions increase remarkably during 5-6 days of incubation. In this period of development, well developed gap junctions consisting of subcompartments of intramembrane particles are found between cell surfaces at both the outer limiting membrane region and the deeper portion of the neural retina. Gap junctions disappear thereafter, and at 7-5 days of incubation, small gap junctions are predominant between cell surfaces at the outer limiting membrane region, while the frequency of gap junctions in the deeper portion is very low. At 9 days of incubation, gap junctions are rarely found. Typical gap junctions are always found between neural retinal cells and those of the pigmented epithelium in embryos up to 7-5 days of incubation. Tight junctions are not found in the neural retina or between neural retina and pigmented epithelium throughout the stages examined.     

AGE-DEPENDENT CHANGE IN THE TRANSDIFFERENTIATION ABILITY OF CHICK NEURAL RETINA IN CELL CULTURE*

We examined how the transdifferentiation ability of neural retinal cells into lens and/or pigment cells in call culture is changed with the development of the donor. Cells dissociated from neural retinas of chick embryos ranging from 3-day-old to the stage immediately before hatching and of 3-day-old chicks were cultured for about 60 days. The results clearly indicated that the transdifferentiation ability decreased with age. The latest developmental stage at which the differentiation of lens cells took place was in 18-day-old embryos. A gradual decrease in this ability was shown by the comparison of crystallin content in cultures prepared from embryos at different stages. The differentiation of pigment cells was recognized in cultures of neural retinas earlier than in 15-day-old embryos. Such loss of the ability of neural retinal cells to transdifferentiate into pigment cells earlier than into lens cells can be partially attributed to inhibitory factors accumulated in medium conditioned with many neuronal cells present in cultures.     

DIFFERENTIATION AND TRANSDIFFERENTIATION IN VITRO OF NEURAL RETINA FROM MUTANT CHICKENS WITH HYPERPLASIC LENS EPITHELIUM1)

Mutant chickens, Hy-1 and Hy-2, show abnormalities in growth and differentiation of the lens epithelium. In this study, neural retinal cells (NR cells) from 3.5-day-old embryos of these mutants were cultured, and the differentiation in vitro was compared with the cells of the normal strain. Hy-1 cells in vitro were characterized by a delay in the first appearance of neuronal cells (N-cells) and by excessive production of this cell type at later stages. By contrast, the Hy-2 cells were indistinguishable from the normal cells in the early phase of culturing. In spite of the marked difference of Hy-1 NR cells in neuronal differentiation up to about 7 days in culture, the transdifferentiation of lens and pigmented cells occurred to a similar extent and with the same time schedule as cultures of normal cells. A number of lentoid bodies were formed by about 10 days. The relative composition of the three major classes of crystallins in transdifferentiated lens cells was almost identical between normal and Hy-1 strains. The results were discussed in comparison with the previous results of cell culture of NR of 8-day embryonic mutant chickens, and it was concluded that the process of transdifferentiation in cell culture is different between NR from 3.5-day-old and 8-day-old embryos.     

Ultracytochemical study on in vitro differentiation of neural retinal cells of chick embryos

In order to study cell differentiation and morphogenesis of neural retina, ultracytochemical examination for acetylcholine esterase (AChE) was carried out on neural retinal cells from 6-day-old chick embryos cultured in monolayer for 20 days. AChE is a suitable marker for identifying cell specificity and structure of cultured neural retinal cells, because its specific localization in the intact chick neural retina has been established. After about 2 weeks of culturing a number of cell aggregates formed on the monolayer sheet of glial cells, in which cell bodies were generally located on the periphery regions while their cellular processes were in the center, forming neuropil structures. Among such peripherally located cells presumptive ganglion, amacrine, bipolar, and photoreceptor cells could be distinguished. In the neuropil structures, some cellular processes had typical ribbon synapses indicating that these structures correspond to the plexiform layers of the retina. We could also classify the neuropils into two types of both from the AChE activity and from the structure of the nerve terminals. These findings indicate that our cell culture system can be used for the study of cell differentiation and histogenesis of retinal cells.     

Demonstration of Transdifferentiation of Neural Retina from Pigmented Retina in Culture1

The formation of neural retina (NR) from retinal pigmented epithelium (RPE) of chick embryos in culture was investigated. In cultures of explants of PRE, depigmented, preretinal foci, consisting of 50 to 100 cells appeared in the pigmented central portion of the explant within three days. Then these depigmented cells increased rapidly in number and by about day 14 they formed characteristic spherical bodies, which were identified as a neural retinal-like structure (NR structure) by electron microscopic observations. Culture of explants of RPE from embryos of different stages showed that the capacity of embryonic RPE to form an NR structure decreased steadily with embryonic age from st. 24 to 27. At and after stage 27, no foci leading to the neural retinal differentiation were formed in the explants. Medium conditioned by cell cultures of chicken embryonic NR, RPE or chondrocytes had no effect on the formation of NR structures by explants of RPE.     

DIFFERENTIATION AND DEDIFFERENTIATION OF RAT LENS EPITHELIAL CELLS IN SHORT- AND LONG-TERM CULTURES

The crystallin synthesis of rat lens cells in cell culture systems was studied in relevance to their terminal differentiation into lens fibers. SDS-gel electrophoresis combined with several immunological techniques showed that γ-crystallin is a fiber-specific lens protein and is not localized in the epithelium of either newborn or adult lenses. When lens epithelial cells of newborn rats were cultured in vitro , α-crystaIlin was detected in many, but not all, of cells cultured for 10 days. Cells with α-crystallin gradually changed their shape into a flattened filmy form and finally differentiated into lentoid bodies. The differentiation of lentoid bodies was also found in cultures of epithelial cells obtained from adult lenses. The molecular constitution of lentoid bodies was the same as that of lens fibers in situ . The differentiation of lentoid bodies occurred successively for 5 months in cultures of lens epithelial cells. Most of the proliferating cells, however, lost α-crystallin during the culture period. Thereafter, they did not show any sign of further differentiation into lens fibers. Four clonal lines were established from these cells. One protein which is specific to the lens epithelium and the neural retina in situ (tentatively named as β_u-crystallin) was maintained in all lines, suggesting that some specific properties of ocular cells remain in the lined cells.     

Oculopotency of embryonic quail pineals as revealed by cell culture studies

Pineal bodies from 8-day-old quail embryos were dissociated and cultured in order to examine their potency for differentiation under in vitro conditions. Polygonal pigment cells and lentoid bodies started to differentiate after about 2 and 4 weeks, respectively. Lentoid bodies were shown immunologically to contain all classes of crystallins. The results indicate that embryonic pineal cells of avian species retain 'oculopotency' to differentiate into several types of ocular cells.     

THE DIFFERENTIATION OF PIGMENT CELLS IN CULTURES OF CHICK EMBRYONIC NEURAL RETINAE

Neural retinal cells of 8–9 day-old chick embryos were differentiated into pigment cells in the conditions of cell culture for about 25 days. The increase of pigment cells in vitro was semi-quantitatively shown, by counting the number of black foci of pigmented cells per plate throughout the culture period. The increase paralleled the increase in the activity of tyrosinase. The addition of a small number of pigment cells freshly dissociated from tapeta to the cultures of neural retinae did not increase the number of black foci in vitro . Electron microscopic observations revealed the morphological differences of melanin granules between those in pigment cells of the neural retinal cultures and those in cultured tapetum cells. It was discussed that pigment cells appearing in the neural retinal cultures were derived from neural retinal cells, but not from contaminated cells of the tapetum.     

Generation of pigmented stripes in albino mice by retroviral marking of neural crest melanoblasts.

The pigment cells of the skin are derived from melanoblasts which originate in the neural crest. The dorsoventral migration of melanoblasts has been visualized in pigment stripes seen in aggregation chimeras, and the width of these bands has suggested that the entire pigmentation of the coat is derived from a small number of founder cells. We have generated mosaic mice by marking single melanoblasts in utero to gain information on the clonal history of pigment-forming cells. A retroviral vector carrying the human tyrosinase gene was constructed and microinjected into neurulating albino mouse embryos. Albino mice are devoid of pigmentation due to deficiency of tyrosinase. Thus, transduction of the wild-type gene into the otherwise normal melanoblasts should rescue the mutant phenotype, giving rise to patches of pigmentation, which correspond to the area colonized by the mitotic progeny of a marked clone. Mosaic animals derived from the injected embryos indeed showed pigmented bands with a width strikingly similar to the 'standard' stripes seen in aggregation chimeras. These results are consistent with the notion that the unit width bands seen in aggregation chimeras represent the clonal progeny of a single melanoblast and verify Mintz's (1967) conclusion that a few founder melanoblasts give rise to coat pigmentation. The pigment cells of the eye are of dual origin: the melanocytes in choroid and outer layer of the iris are derived from the neural crest and those in the pigment layer of the retina from the neuroepithelium of the optic cup. Marked clones in both lineages were observed in the eyes of many mosaic animals.