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.     

Transdifferentiation of putative neuronal cells of neural retina into lens: A demonstration by chick-quail chimeric cultures

Summary To elucidate the cell-type origin of lens cells, which differentiate in stationary cultures of neural retina, chimeric cultures between chick and quail cells were made to recombine xenoplastically the different cell fractions separated from 8- to 9-day cultures of 3.5-day-old embryonic neural retinal cells by means of centrifugation in Percoll. Extensive lentoidogenesis occurred in the recombination of the N2-fraction (consisting mostly of small round cells) with the E-fraction (containing a number of flattened epithelial cells). Taking advantage of the difference in electrophoretic mobility of chick and quail -crystallin, it was shown that this lens-specific protein, synthesized in the chimeric cultures, was mostly of the species-specificity of N2. Microscopic observations of histological sections of cell sheets of quail N2- and chick E-fraction chimeric cultures revealed that most cells with -crystallin, as identified by means of immunohistological detection, are provided with a nuclear marker characteristic of quail. By determining the level of activity of choline acetyltransferase and by examining the stainability with a fluorescent dye (Merocyanine-540), it was suggested that cells in the N2-fraction are primitive neuroblast-like cells. Thus, we can conclude that putative neuronal cells in early cultures of avian embryonic neural retina can transdifferentiate into lens cells.     

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.     

Possible demonstration of multipotential nature of embryonic neural retina by clonal cell culture.

The possible multipotential nature of the neural retina of early chick embryos was examined by the technique of clonal cell culture. Cultures were prepared from cells dissociated from freshly excised neural retinas of 3.5-day-old chick embryos or from cells harvested from primary highdensity cultures. The following four colony types were obtained: colonies differentiating into “lentoid bodies”; colonies with pigment cells; colonies with both “lentoid bodies” and pigment cells; and colonies comprised entirely of unidentifiable cells. Neuronal differentiation occurred frequently in the early stages of culture (up to about 10 days). In some of these neuronal colonies, “lentoid bodies” and, rarely, both “lentoid bodies” and pigment cells differentiated after a further culture period of up to 30 days. Secondary colonies established from primary colonies after 9–10 days demonstrated that these original colonies fell into four different categories: those giving rise to secondary colonies containing only “lentoid bodies,” those giving rise to pigmented colonies only, those developing both lentoid and pigmented colonies, and finally those which gave rise to secondary colonies of all three types, lentoid, pigmented, and mixed colonies. When primary pigmented colonies were recloned at about 30 days after inoculation, the differentiated pigment cells transdifferentiated into lens. Whether multispecific colonies were really of clonal origin or not is discussed. The possible presence of a multipotent progenitor cell able to give rise to multispecific clones in the neural retina of 3.5-day-old chick embryos is suggested. A sequence of differentiation starting from multipotent neural retinal cells to be terminated with lens through the differentiation of neuronal and pigment cells is hypothetically proposed.     

COMPARISON OF NEURONAL AND LENS PHENOTYPE EXPRESSION IN THE TRANSDIFFERENTIATING CULTURES OF NUERAL RETINA WITH DIFFERENT CULTURE MEDIA*

The effects of three different culture media (Eagle's MEM, F-12 and L-15) on the transdifferentiation of 8-day chick embryonic neural retina into lens cells, were examined with respect to the expression of two phenotypes. One type referred to neuronal specificity (as represented by the level of cholineacetyl-transferase, CAT, activity) and the other to lens specificity (as represented by content of α-and δ-crystallin). In 7-day cell cultures before the visible differentiation of lentoid bodies, CAT activity was detected in all media. But, its level was about 9 times higher in cultures with L-15 than in those with MEM and 3 times higher than in F-12. In 26-day cultures, CAT activity was practically undetectable. The production of α-and δ-crystallin was detected in cultures at 26 days. There were quantitative differences in the crystallin content with different media, and it was highest in cultures with L-15. The results indicate that conditions most favourable to the maintenance of the neuronal specificity in cell cultures of neural retina, can also support the most extensive transdifferentiation. The possibility of direct transdifferentiation of once neuronally specified cells into lens cells in cultures with L-15 has been suggested to explain the present results.     

Pathways of differentiation in chick embryo neuroretinal cultures

Markers of neuronal cell differentiation (GABA accumulation, choline acetyltransferase activity) are shown to increase initially and then decline sharply in monolayer cultures of 9 day embryo neuroretinal (NR) cells. A glial marker (glutamine synthetase, GSase) is precociously inducible by hydrocortisone (HC) in dens "monolayer' NR cultures (containing aggregates of neuronal cells overlying the glian sheet) as well as in chick embryo retinal explants. The induced level of GSase activity is not maintained in the continued presence of HC, but rather declines by 20 days in vitro. Choline acetyltransferase (CAT) activity is higher in HC-treated cultures than in controls only during the period when induced GSase activity is detectable. Furthermore, the subsequent transdifferentiation of lens cells (monitored as delta crystalline content) in these cultures is delayed by 10 days and much reduced in extent when HC is present throughout the culture period. We suggest a simple model to account for these results, on the basis of recent evidence that lens cells are derived mainly from the retinal epithelial cells (immature Müller glia) of 9-day embryonic NR, and that transdifferentiation results from a change in cell determination during the early stages of "monolayers' culture. In outline, our model proposes that early determination of the retinal glia is associated with a decline of neuronal cell markers (dedifferentiation) followed eventually by loss of the neuronal cells. Hydrocortisone, by inducing transient glial cell differentiation (GSase activity), both prolongs the expression of a neuronal marker (CAT) and also reduces later transdifferentiation into lens.     

Pathways of Differentiation in Chick Embryo Neuroretinal Cultures

Markers of neuronal cell differentiation (GABA accumulation, choline acetyltransferase activity) are shown to increase initially and then decline sharply in monolayer cultures of 9 day embryo neuroretinal (NR) cells. A glial marker (glutamine synthetase, GSase) is precociously inducible by hydrocortisone (HC) in dense'monolayer' NR cultures (containing aggregates of neuronal cells overlying the glial sheet) as well as in chick embryo retinal explants. The induced level of GSase activity is not maintained in the continued presence of HC, but rather declines by 20 days in vitro. Choline acetyltransferase (CAT) activity is higher in HC-treated cultures than in controls only during the period when induced GSase activity is detectable. Furthermore, the subsequent transdifferentiation of lens cells (monitored as δ crystallin content) in these cultures is delayed by 10 days and much reduced in extent when HC is present throughout the culture period.
We suggest a simple model to account for these results, on the basis of recent evidence that lens cells are derived mainly from the retinal epithelial cells (immature Müller glia) of 9-day embryonic NR, and that transdifferentiation results from a change in cell determination during the early stages of'monolayer' culture. In outline, our model proposes that early dedetermination of the retinal glia is associated with a decline of neuronal cell markers (dedifferentiation) followed eventually by loss of the neuronal cells. Hydrocortisone, by inducing transient glial cell differentiation (GSase activity), both prolongs the expression of a neuronal marker (CAT) and also reduces later transdifferentiation into lens.     

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.     

An attempt to assay the state of determination by using transfected genes as probes in transdifferentiation of neural retina into lens

Hybrid genes coding for chloramphenicol acetyltransferase (CAT) with a non-specific retroviral, lens-specific delta-crystallin or lens-specific alpha-crystallin promoters were constructed to transfect the transdifferentiating (lentoidogenic) and non-transdifferentiating (non-lentoidogenic) cultures of chicken embryonic neural retina for assaying the state of determination towards lens differentiation. The expression occurred only when CAT genes with lens-specific promoters were transfected to the cultures maintained in the conditions permissive to lentoidogenesis. The expression of these exogenous, lens-specific CAT genes began at stages of culturing that were earlier than the expression of endogenous crystallin. Presumably, there are two steps in the transdifferentiation of neural retina into lens; acquisition of capacity to express crystallin genes and derepression of the endogenous crystallin genes.     

pp60c-src expression in transdifferentiating cultures of embryonic chick neural retina cells

Chick embryo neural retinal cells transdifferentiate extensively into lens cells when cultured in Eagle's MEM containing horse and fetal calf sera (FHMEM). Such cultures express elevated levels of pp60c-src-associated tyrosine kinase activity relative to parallel cultures prevented from transdifferentiating by the addition of supplementary glucose (FHGMEM) or replacement of MEM by medium 199 (F199). Northern blotting and in vitro translation studies suggest that c-src mRNA levels are only slightly higher in late transdifferentiating (FHMEM) cultures as compared to parallel blocked (FHGMEM or F199) cultures. By immunocytochemical staining, we show that pp60c-src protein is largely localized in cell groups undergoing conversion into lens (i.e. expressing delta crystallin) in late FHMEM cultures. Initial studies of pp60c-src in chick lens tissues during development indicate that higher kinase activity is found in the epithelial cells relative to mature lens fibres. Thus pp60c-src may be expressed both during the differentiation of lens cells in vivo and during the transdifferentiation of neural retina cells into lens in vitro.     

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.     

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.     

The pattern of DNA methylation in the delta-crystallin genes in transdifferentiating neural retina cultures

Terminally differentiated lens fibre cells are formed in the vertebrate lens throughout life. Lens fibre cells may also be obtained by an in vitro process termed transdifferentiation, from certain tissues of different developmental origin from lens, such as embryo neural retina. delta-Crystallin is the major protein in the chick embryo lens fibre cells, and also in transdifferentiated lens cells obtained from cultured embryonic neural retina. Lens crystallin proteins and mRNA are present at low levels in the intact embryonic neural retina but are no longer detectable in the early stages of neural retina cell culture. However, levels rise steeply in the later stages and crystallins become the major products in terminally transdifferentiating neural retina cultures. We have used this system to test the hypothesis that the patterns of DNA methylation in particular genes are correlated with gene expression. A number of developmentally regulated genes have been found to be undermethylated in tissues where they are expressed, and methylated in tissues where they are not. However this correspondence does not always hold true. Eight-day-old embryonic neural retina was cultured for the period of time during which crystallin gene expression increases 100-fold. DNA methylation in the delta-crystallin gene region was analysed at several stages of cell culture by using the restriction endonucleases HpaII and MspI which cleave at the sequence CCGG. The former enzyme cannot cleave internally methylated cytosine (CmCGG) while the latter cannot cleave externally methylated cytosine (mCCGG). We detect no change in the methylation of CCGG sites within the delta-crystallin gene regions during transdifferentiation. Since dramatic changes in delta-crystallin gene expression occur during this process we conclude that large scale alterations in the pattern of DNA methylation are not a necessary accompaniment to changes in gene activity.     

Differential effects of culture media on normal and foreign differentiation pathways followed by chick embryo neuroretinal cells in vitro

Three different culture media, Ham's F-12, medium 199, and Eagle's minimal essential medium (MEM), were compared with respect to the expression of neuronal (choline acetyl transferase activity: CAT) and glial (hydrocortisone-induced glutamine synthetase activity; GSase) markers of normal differentiation in cultures of 9-day chick embryo neuroretinal cells, and also with respect to the accumulation of a lens marker (delta crystallin) during so-called 'transdifferentiation' in these cultures. MEM allows transient expression of both CAT and GSase activities in early cultures, but also permits extensive delta crystallin accumulation at later stages. F-12 medium gives somewhat higher levels of CAT and GSase activities, the former being noticeably prolonged as compared with parallel MEM cultures; delta crystallin accumulation, however, is largely inhibited in F-12 cultures. By contrast, medium 199 permits only low levels of CAT and GSase activities, perhaps because the neuronal cells are distributed individually over the glial cell sheet in 199 cultures, rather than forming aggregates as in MEM or F-12 cultures. Medium 199 also blocks delta crystallin accumulation. The results of medium changeover between 'transdifferentiation'-permissive (MEM) and non-permissive (199, F-12) conditions suggest: (a) that potential lens precursor cells (whatever their nature) survive in F-12 medium for prolonged periods without extensive expression of the lens phenotype; (b) that such precursor cells become committed to subsequent differentiation as lens cells between 10 and 20 days of culture in permissive MEM medium (as judged by the accumulation of delta crystallin following transfer into F-12); and (c) that medium 199 can block expression of the lens phenotype even in cells already committed (by the above criteria) to lens differentiation, as for instance after 30 days of preculture in MEM.     

Differential effects of culture media on normal and foreign differentiation pathways followed by chick embryo neuroretinal cells in vitro

Abstract. Three different culture media, Ham's F-12, medium 199, and Eagle's minimal essential medium (MEM), were compared with respect to the expression of neuronal (choline acetyl transferase activity: CAT) and glial (hydrocortisone-induced glutamine synthetase activity; GSase) markers of normal differentiation in cultures of 9-day chick embryo neuroretinal cells, and also with respect to the accumulation of a lens marker (δ crystallin) during so-called 'transdifferentiation' in these cultures.
MEM allows transient expression of both CAT and GSase activities in early cultures, but also permits extensive δ crystallin accumulation at later stages. F-12 medium gives somewhat higher levels of CAT and GSase activities, the former being noticeably prolonged as compared with parallel MEM cultures; δ crystallin accumulation, however, is largely inhibited in F-12 cultures. By contrast, medium 199 permits only low levels of CAT and GSase activities, perhaps because the neuronal cells are distributed individually over the glial cell sheet in 199 cultures, rather than forming aggregates as in MEM or F–12 cultures. Medium 199 also blocks δ crystallin accumulation.
The results of medium changeover between 'transdifferentiation'-permissive (MEM) and non-permissive (199, F-12) conditions suggest: (a) that potential lens precursor cells (whatever their nature) survive in F-12 medium for prolonged periods without extensive expression of the lens phenotype; (b) that such precursor cells become committed to subsequent differentiation as lens cells between 10 and 20 days of culture in permissive MEM medium (as judged by the accumulation of δ crystallin following transfer into F-12); and (c) that medium 199 can block expression of the lens phenotype even in cells already committed (by the above criteria) to lens differentiation, as for instance after 30 days of preculture in MEM.     

Expression of Toxin Receptors on Cell Surfaces in Transdifferentiating Cultures of Neural Retina

It has often been asked which of the cell types found during the early stages of culturing embryonic chick neural retina can undergo transdifferentiation into lens in vitro. Since neuronal cell-surface toxin receptors are maintained in NR cultures for much longer than internal neuronal enzymes (e.g. choline acetyltransferase), and since the transdifferentiation process can be greatly accelerated by preparing reaggregates of neural retina cells after about 10 days of preculture as "monolayers", a direct test of this question became feasible. 7 or 9 day embryonic chick neural retina cells, precultured for 10–12 days as monolayers, were dissociated and reaggregated under continuous gyration. Reaggregates were maintained for 8 days in the presence of either tetanus toxin or FITC-conjugated α-bungarotoxin, to permit surface-bound toxins to become internalised via receptor turnover. The reaggregates were then dissociated, stained with rabbit antitoxin and FITC-conjugated anti-antibody in the case of tetanus toxin-labelled material, and restained with a rat or mouse antibody against chick δ crystallin followed by the appropriate rhodamine-conjugated anti-antibody. Although both FITC/toxin-labelled cells (putative neurones) and rhodamine/δ crystallin-labelled cells (transdifferentiated lens cells) were abundant, no examples of double-labelled cells were observed with 9 day starting material, and only a very few with 7 day starting material. We conclude that the vast majority of differentiated neuronal cells expressing surface receptors for these toxins do not transdifferentiate directly into lens cells.     

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.     

The control of δ-crystallin gene expression during lens cell development: Dissociation of cell elongation,cell division, δ-crystallin synthesis,and δ-crystallin mRNA accumulation

Previous studies have shown that freshly explanted 6-day-old embryonic chick lens epithelial cells elongate, differentially increase their synthesis of δ-crystallin, and accumulate δ-crystallin mRNA when cultured with fetal calf serum; in contrast, precultured serum-starved 6-day-old and freshly explanted 19-day-old embryonic epithelial cells divide when treated with fetal calf serum. We have explored whether the stimulation of δ-crystallin gene expression (as measured by δ-crystallin synthesis and δ-crystallin mRNA accumulation) is affected by inhibiting lens cell elongation with colchicine, and whether δ-crystallin gene expression is increased in lens epithelial cells stimulated to divide by treatment with fetal calf serum, as it is in those stimulated to elongate by treatment with serum. Three new findings were made in this study. First, the stimulation of δ-crystallin gene expression does not require elongation of the cultured lens cells. Second, a decreased proportion of δ-crystallin synthesis is observed in lens epithelial cells during normal development and during serum starvation; in neither case is this decrease associated with a reduction in the number of δ-crystallin mRNA sequences per cell. Finally, serum stimulation of lens cell division does not increase the proportion of δ-crystallin synthesis, but can promote the accumulation of δ-crystallin mRNA. Thus, the relative proportion of δ-crystallin synthesized during chick lens development is not solely a function of the number of δ-crystallin mRNA sequences in the lens cells.     

Tissue- and species-specific promoter elements of rat gamma-crystallin genes.

The 5' flanking regions of the six rat gamma-crystallin genes (gamma A-gamma F) are all capable of conferring lens-specific expression to the bacterial chloramphenicol acetyl transferase (CAT) reporter gene in either transdifferentiating chicken neural retina cells or mouse lens epithelial cells. Deletion mapping of the most active gamma-crystallin promoter region, the gamma D region, showed that at least three elements are required for maximal expression in mouse lens epithelial cells: element(s) located between -200 and -106, a conserved CG rich region around position -75, and a CG stretch around -15. The region between -200 and -106 was dispensable in transdifferentiating chicken neural retina cells, which instead required the region between -106 and -78. The maximal activity of the gamma E and gamma F promoters was also dependent upon the integrity of the conserved CG region located around -75. A synthetic oligonucleotide containing this sequence was capable of lens-specific enhancement of the activity of the tk promoter in transdifferentiating chicken neural retina cells but not in mouse lens epithelial cells. Our results further show that this region may contain a silencer element, active in non-lens tissues, as well.