Origin of lentoids in experimental teratomas derived from early postimplantation rat embryos

Summary Experimental teratomas derived from renal isografts of early postimplantation rat embryonic shields were analysed histologically for the presence of lentoids and their relationship with other tissues within the tumour. The observations permit the conclusion that in teratomas lentoids originate either from the retinal epithelium or from the ependymal cells of the brain ventricle     

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.     

Formation of lentoids from retina gliocytes: ultrastructural study

In primary monolayer cultures of dispersed neural retina cells from 13-day chick embryo, gliocytes (Müller glia cells) multiply and rapidly change into a lentoidal (lens-like) phenotype. They express lens proteins, including MP26 (a lens plasma-membrane antigen) and ultra-structurally appear to resemble lens cells. A significant aspect of this modification is that the glia-derived lentoidal cells no longer display contact-affinity for neurons but become preferentially adhesive to each other; in aggregates, they assemble into compact lentoids. A likely explanation for this change in cell affinities is that the modified gliocytes express little or no R-cognin, a retinal cell-surface antigen implicated in mutual recognition and adhesion of retina cells. Although lentoidal cells express MP26, a gap-junction component in the lens, no gap junctions could be found in the lentoids.     

Transdifferentiation of Adult Frog Iris in Retina or Lens by Exogeneous Influences

The mechanisms of transdifferentiation of iris epithelial cells of Rana temporaria (Anura) in culture depending on influences from different sources were studied. In terminally differentiated iris cells, the process of transdifferentiation is initiated by dedifferentiation. Melanosomes are shed from iris cells due to cell surface activity. After depigmentation, iris epithelial cells become capable of proliferating and competent to react to the influences of various exogenous factors. Under the influence of retinal factors secreted by lentectomized tadpole eyes, both dorsal and ventral irises are converted to neural retina. Under the influence of factors from eye vesicles, the irises are converted to neural retina as well. Similar results were obtained in transfilter experiments, in which a 3-day period of transfilter interaction between the irises and eye vesicles ensured depigmentation of the iris followed by transdifferentiation into complete NR with visual receptor. Lentoid formation occurred under the influence of adult frog lens epithelium. Immunofluorescent analysis confirmed the lens nature of the lentoids. In control experiments under the conditions of the tadpole eye orbit, in which programming influences were absent, iris epithelial cells remained unaffected.
The problem of true cell-reprogramming to new differentiation in contrast to expression of inherent properties of the iris epithelial cells is discussed.     

Transferrin enhances lentoid differentiation in rat egg cylinders cultivated in a chemically defined medium

Rat egg cylinders at the primitive streak stage were grown in modified organ culture for 2 weeks using a chemically-defined medium. The purpose of the experiment was to determine whether the terminal tissue differentiation is modified by human transferrin. The control sets were grown in medium with or without rat serum. In explants treated with transferrin, groups of atypical cells of the ocular lens (lentoids) appeared more frequently than in both control sets; however neuroblasts were observed as often as in the serum-supplemented medium. Bovine serum albumin (BSA) stimulated the differentiation of neuroblasts but did not promote lentoid formation. We conclude that human transferrin does stimulate the differentiation of lentoids in rat embryonic explants, but the mechanism of its action remains unknown.     

Induction of alpha- and beta-crystallin synthesis in organ cultures of the adenohypophyseal anlage of chickens as affected by 5-iododeoxyuridine and 5-bromodeoxyuridine

The effects of 5-iododeoxyuridine and 5-bromodeoxyuridine on differentiation of the cells of adenohypophysis rudiment from 3, 4, and 5 day old chick embryos were studied in the in vitro organ culture. On the 7th day of cultivation most explants from 3 and 4 day old embryos formed lentoids and individual cells with the lens phenotype among the adenohypophysis tissue. Alpha-, beta- and delta-crystalline were immunochemically detected in them. When cultivating explants from 5 day old embryos, no lentoids formed. But the immunochemical study of serial sections made it possible to detect in individual explants single alpha-crystalline-containing cells. There is a period in the development of chick adenohypophysis, which lasts five days of incubation and during which the adenohypophysis rudiment retained its capacity for lens differentiation despite the fact that it is already determined in the adenohypophysis direction.     

Differentiation of lens- and Iris-like tissue in explants of the anterior part of the frog neural plate

Summary The differentiation was studied of presumptive eye material developing in the absence of ectoderm. Explants were made of the anterior (forebrain- and eye-forming) part of the neural plate, without the lateral neural folds, of early to mid-neurulae ofRana temporaria andR. esculenta. The underlying endomesoderm as well as the outer layer of the neural plate were removed prior to explantation. Consequently the explants did not become surrounded by epidermis. The explants segregated into a mass of forebrain tissue and a single retina, which did not assume the typical cup shape. In between these two components an interzone developed, consisting of incompletely differentiated layers of iris tissue. In the interzone typical lentoids, as well as lentoids continuous with other tissue components, differentiated. The formation of lentoids in the absence of ectoderm is discussed in terms of the availability of a lens-inducing agent. It is assumed that in the interzone the lens-inducing agent acts on tissue components which are competent for lens formation. The formation of lens-like tissue may be regarded as analogous to lens regeneration in newts.The author wishes to express her sincere appreciation to Prof. G. V. Lopashov for his advice and encouragement throughout the course of this study, to Mrs. Nina A. Ivanova for expert technical assistance, and to Dr. J. Faber (Hubrecht Laboratory, Utrecht) for the correction of the English.     

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.     

Cellular and molecular background of Wolffian lens regeneration

Based on studies of wolffian lens regeneration in the newt, in which the lens can be regenerated from the iris pigmented epithelium, we have shown by cell culture studies that the capacity of lens transdifferentiation is not limited to the newt cells, but widely conserved in pigmented epithelial cells (PECs) of chick and quail embryos and even of human fetuses. Recently, we have established a unique in vitro model system of chick embryonic PECs. In this culture system we are able to control each step of transdifferentiation from PECs into lens cells by regulating culture conditions and to produce a homogeneous cell population with potential for synchronous differentiation into either lens or pigment cell phenotype. These multipotent (at least bipotent) cells showed cellular characteristics resembling neoplastic cells in many ways. They did not express both lens and pigment cell specific genes analyzed so far, except δ-crystallin gene, which is expressed in developing lens of chick embryos. It has been proved by application of cell culture procedures of the system that PECs dissociated from fully-grown human eyes readily transdifferentiated into lens phenotypes in the manner observed in chick embryo PECs. In addition, we could predict that molecules detected in either cell surface or intercellular space stabilized the differentiated state of PECs in the newt and that the loss of these molecules might be one of the key steps of lens regeneration from the iris epithelium.     

Cellular distribution of lens epithelium-derived growth factor (LEDGF) in the rat eye: loss of LEDGF from nuclei of differentiating cells

Lens epithelium-derived growth factor (LEDGF) enhances the survival and growth of cells. To understand LEDGF's spatial localization and its putative function(s) during proliferation and differentiation, we localized LEDGF during terminal differentiation in whole rat lenses, lens epithelial cell (LEC) explants stimulated with FGF-2, and insulin, iris, human LECs with lentoids. In addition, intracellular localization of LEDGF was performed in other ocular tissues: ciliary body, retina, and cornea. We found the immunopositivity of nuclear LEDGF decreased in LECs of the equatorial region. In contrast, immunopositivity of LEDGF was detected in the cytoplasm of LECs and superficial fiber cells. After treating LEC explants with FGF-2 and insulin, which are known to be differentiating factors for LECs, the nuclei of these cells showed no LEDGF immunopositivity, but explants did express p57(kip2), a differentiation marker protein. Also, immunopositive LEDGF was not detected in the nuclei of differentiated cells, lentoid body, and corneal epithelial cells. This demonstrated that the loss of LEDGF from the nucleus may be associated with the process of terminal differentiation that might be in some way common with the biochemical mechanisms of apoptosis. The spatial and temporal distribution of LEDGF in the present study also provides a vision for further investigation as to how this protein is involved in cell fate determination.     

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.     

The cell cycle of cultured iris epithelial cells: Its possible role in cell-type conversion

Cell cycle parameters were estimated in primary cultures of iris epithelial cells, obtained from explanted dorsal and ventral irises of adult newts (Notophthalmus viridescens). No significant difference was found between parameters of dorsal and ventral iris epithelial cell cultures. Compared with the total cell cycle time of iris epithelial cells in situ in the pathway of conversion, that of cultured iris epithelial cells is longer by a factor of 1.88. The results support the working hypothesis that the basic requirement for conversion of iris epithelial cells into lens cells is the passage of a definite number of cell cycles instead of the inductive influence of neural retina.     

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.     

FGF-mediated induction of ciliary body tissue in the chick eye

Upon morphogenesis, the simple neuroepithelium of the optic vesicle gives rise to four basic tissues in the vertebrate optic cup: pigmented epithelium, sensory neural retina, secretory ciliary body and muscular iris. Pigmented epithelium and neural retina are established through interactions with specific environments and signals: periocular mesenchyme/BMP specifies pigmented epithelium and surface ectoderm/FGF specifies neural retina. The anterior portions (iris and ciliary body) are specified through interactions with lens although the molecular mechanisms of induction have not been deciphered. As lens is a source of FGF, we examined whether this factor was involved in inducing ciliary body. We forced the pigmented epithelium of the embryonic chick eye to express FGF4. Infected cells and their immediate neighbors were transformed into neural retina. At a distance from the FGF signal, the tissue transitioned back into pigmented epithelium. Ciliary body tissue was found in the transitioning zone. The ectopic ciliary body was never in contact with the lens tissue. In order to assess the contribution of the lens on the specification of normal ciliary body, we created optic cups in which the lens had been removed while still pre-lens ectoderm. Ciliary body tissue was identified in the anterior portion of lens-less optic cups. We propose that the ciliary body may be specified at optic vesicle stages, at the same developmental stage when the neural retina and pigmented epithelium are specified and we present a model as to how this could be accomplished through overlapping BMP and FGF signals.     

THE INFLUENCE OF GROWTH-INHIBITING AND GROWTH-PROMOTING MEDIUM CONDITIONS ON CRYSTALLIN ACCUMULATION IN TRANSDIFFERENTIATING CULTURES OF EMBRYONIC CHICK NEURAL RETINA

The effects of media containing undialysed serum (controls) or dialysed serum with or without ascorbic acid, were compared during the second half of the 41-day culture period in embryonic chick neural retina cultures, which had all been grown in control medium prior to 19 days. Conditions permitting greatest culture growth (controls) showed earlier and more extensive development of lentoids, greater accumulation of total crystallin and a higher proportion of δ relative to α+β crystallins. Conditions allowing least culture growth (dialysed serum) gave converse results throughout. Thus changes in culture growth rate apparently affect δ crystallin production more than α or β crystallin production. Insulin promotes growth in neural retina cultures, whether present throughout the culture period (in this case 31 days), or only from 18 days onwards. The frequency and survival of putative neuronal cell aggregates are both increased by insulin during the first 18 days of culture. Delta crystallin production during subsequent transdifferentiation is selectively promoted by insulin when present throughout, but this effect is largely obviated when insulin is present only from 18 days onwards. This anomaly could arise through percursor cell selection during the earlier phases of culture, since it is possible that some (not all) lentoids may be derived from aggregates of neuronal-like cells in neural retina cultures. Thus precursor cell selection as well as culture growth rate may influence the pattern of crystallin production during transdifferentiation.     

Role of the neural retina in newt (Notophthalmus viridescens) lens regeneration in vitro

Removal of the lens from the eye of an adult newt (Notophthalmus viridescens) is followed by regeneration of a new lens from the dorsal iris epithelial cells at the pupillary margin. This process is dependent upon the neural retina for its normal completion in vivo and in vitro. To examine the relationship between the retina and lens regeneration, we have conducted experiments that delimit the time period during which the retinal presence is critical (in vivo) and have investigated the influence of extracts of the retina on the progress of regeneration (in vitro). In vivo, removal of the retina at day 11 seriously retards further progression of regeneration while removal of the retina at day 15 does not retard regeneration significantly. This defines a "critical period" in regeneration of the lens during which the retina is required. Explantation of regenerates 11 or 12 days after lentectomy to organ culture medium enriched with either crude retinal homogenate or extracts prepared from chick or bovine retinas according to Courty et al. ('85, Biochimie, 67:265-269) reveals that the progress of regeneration can be supported in culture by the crude extract. This is the first demonstration of complete iris-lens transformation in culture in the presence of retinal extract. It is possible that the retina acts indirectly by promoting passage of the iris epithelial cells through the critical number of mitoses required before redifferentiation into lens cells can occur (as proposed by Yamada, '77, Monogr. Dev. Biol., 13:126). It is also possible that the retina acts by directly instructing the iris cells to redifferentiate.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Transformation of Iris into Lens in vitro and its Dependency on Neural Retina

Upon lentectomy of adult newt eyes, the dorsal iris epithelium produces a cell population that develops into a new lens. The tissue transformation can be completed not only in the isolated lentectomized eye cultured as a whole, but also in the isolated newt normal dorsal iris combined with the retina of frog larvae in vitro. In this study, 93% of such cultures produced lens tissue made up of newt cells. Well-differentiated lens fibre cells were formed which showed positive immunofluorescence for gamma crystallins. When the isolated dorsal iris epithelium was cultured under the same conditions, well-differentiated lens tissue was again formed in 95% of the cases, suggesting that iris epithelial cells and not iris stromal cells are responsible for lens formation. In contrast, the combination of newt ventral iris with frog retina did not produce any newt lens tissue. No lens tissue was produced when the dorsal iris was cultured with newt spleen or lung, although a considerable number of iris epithelial cells became depigmented. Isolated normal dorsal iris or normal dorsal iris epithelium cultured alone infrequently produced a population of depigmented cells but failed to form lens tissue. On the basis of the present and earlier data, it is concluded that in Wolffian lens regeneration in situ , interaction of the iris epithelial cells with the retina plays a decisive role. However, it is suggested that the iris epithelial cells may have an inherent tendency towards lens formation, and that the factor(s) from the retina facilitates the realization of this tendency, rather than instructing the cells to produce lens. The reported experiments provide the first direct evidence for the existence of cellular metaplasia by demonstrating transformation of fully differentiated iris epithelial cells into lens 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.     

Retroviral overexpression of bcl-2 in the embryonic chick lens influences denucleation in differentiating lens fiber cells

During the course of their differentiation, embryonic lens fibers undergo loss of their cytoplasmic organelles and nuclei. The denucleation process bears similarities to the nuclear breakdown that occurs during apoptosis. This has given rise to the hypothesis that this denucleation is analogous to apoptosis, but without the plasma membrane changes characteristic of apoptotic cell death. Previous work has shown that several members of the apoptotic cascade are active during denucleation. Here, we have overexpressed the anti-apoptotic molecule bcl-2 in developing lenses of the 8-day-old chick embryo in ovo, using the replication-competent retrovirus RCAS. We find that lenses overexpressing bcl-2 show varying degrees of distortion in comparison with untreated and negative insert controls, including a more spherical shape and disorganized fiber cells. All overexpressing lenses showed significantly higher numbers of smaller nuclei in the lens core, where denucleation begins. There was no change in cell size or pattern of proliferation. These in vivo results were confirmed in vitro using lens epithelial cell cultures, which differentiate into lentoids. The lentoids in treated cultures showed the same effect on nuclear number and size. We further found that in lenses overexpressing bcl-2 there was a reduction in the activation of caspase-9 and the cleavage of the caspase substrate DFF45, and, in the lens core, a failure of the nuclear chromatin to condense. These results provide strong support for the view that embryonic lens fiber cell denucleation is analogous to the nuclear degradation that occurs during apoptosis, and that similar control pathways are involved in both these phenomena.