Evaluation of different procedures for the dissociation of retinal pigmented epithelium into single viable cells

Retinal pigmented epithelium (RPE) from 7-day-old chicken embryos (stages 29 to 31) was isolated and dissociated into single cells using different procedures. The results were assessed in two ways. (1) The yield of single RPE cells per embryo was determined, and their ability to form pigmented colonies in clonal culture was tested. The most efficient and gentle procedure included isolation of the RPE in EDTA solution, trypsinization at low temperature and low enzyme concentration in the presence of EDTA, followed by incubation in culture medium for up to 4 hr. The completely dissociated cells thus obtained had a much higher plating efficiency and more uniform pattern of colony growth and differentiation than those obtained under any other conditions tested. (2) The effects of different treatments on cell junctions and morphological integrity of the cells were determined by transmission electron microscopy. EDTA solution yielded excellent separation of the epithelial sheet from the mesenchyme by dissociating it from Bruch's membrane, but had little effect on the junctions between adjacent RPE cells. Trypsinization of the epithelium under various conditions separated the basal lateral cell borders and caused loss of gap junctions, but left many cells still joined by apical tight junctions. Final disruption of the tight junctions occurred during recovery of the trypsinized cells in culture medium and was accompanied by dedifferentiation of the RPE 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.     

A clonal approach to the problem of neural crest determination.

A fundamental question regarding neural crest development is the possible pluripotential nature of this embryonic tissue. As a first step in examining this problem, clonal techniques are used to produce homogeneous populations of crest cells. Primary cultures of these cells are obtained by explanting neural tubes from Japanese quail in vitro and allowing crest cells to migrate away. The explant is removed, the outgrowth is isolated, dissociated with trypsin, and the cells plated at clonal density. Colonies derived in this manner fall into the following categories: all cells of the colony pigmented; none of the cells pigmented; and some of the cells pigmented, the remainder unpigmented. Pigmented colonies generally arise from small, round cells whereas the non-pigmented colonies usually originate from large, flattened polymorphous cells. Differentiation of melanocytes does not preclude their continued proliferation. The pigment phenotype, in addition, is stable through at least 25 generations. That the mixed colonies, in fact, are clonally derived is shown by physically isolating single cells. The identity of the non-pigment cells was not established in the present work. A possible neural fate is suggested, however, since nerve-like cells develop after the petri plates become overgrown. Neural clones did not form even though nerve growth factor activity is present as a normal constituent of the culture medium and was added as a supplement in some instances. These techniques permit the preparation of large, homogeneous populations of neural crest cells and afford an opportunity to examine aspects of crest determination heretofore impossible to study.     

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.     

The factors that promote the development of symmetry properties in aggregates from dissociated echinoid embryos

Summary Embryos of Hemicentrotus pulcherrimus at the 16 cell, 400 cell or mesenchyme blastula stage of development were dissociated into single cells. The cells were reaggregated, and the development of individual aggregates was monitored. Only aggregates from 16 cell embryos developed into pluteus-like larvae with radial or bilateral symmetry. When embryos at these three developmental stages were incompletely dissociated so that there were mixtures of single cells and groups of undissociated cells, the percentage of aggregates from 16 cell embryos that developed in a pluteus-like manner was greater than in aggregates from completely dissociated 16 cell embryos. Also a small percentage of aggregates from 400 cell embryos now developed into pluteus-like larvae. In both of these experiments small aggregates tend to develop in a more normal manner than larger aggregates.In order to test the role of undissociated cells in promoting pluteus-like development in aggregates from incompletely dissociated blastula stage embryos, pieces of intact animal, lateral, or vegetal blastula wall were grafted to aggregates formed from completely dissociated embryos. While each kind of graft improved the ability of the aggregate to develop in a pluteus-like manner, grafts of vegetal blastula wall were most effective. In an aggregate, a graft differentiates according to its presumptive fate and influences the cells of the aggregate to differentiate in an appropriate manner. The ability of the graft to influence the development of the other cells in the aggregate depends on the developmental stage of the cells that make up the aggregate and the size of the aggregate.     

An analysis of the distribution of clone cells in the retinal pigment epithelium from chimeric mice

The quantity of pigmented and unpigmented cells was estimated in the retinal pigment epithelium (RPE) in ten newborn and five 20-days old aggregated chimaeric mice C/C----c/c. A strong correlation was shown in the proportion of cells of the paternal genotypes either in the whole RPE of right and left eyes or in its separate regions, i.e. dorsal, central, ventral. Random distribution was revealed in these RPE cells clones. A high correlation was shown between the number of RPE pigmented cells and percentage of coat pigmentation.     

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.     

Novel method for the establishment of cardiomyocytes derived from rat embryonic stem cells in vitro

Cardiomyocytes were differentiated from embryonic stem cells (ES cells) derived from spontaneous dwarf rats (SDR) in vitro. The two-cell stage embryos were cultured in alpha-MEM supplemented with 10% fetal calf serum and embryotrophic factors (ETF). ETF were isolated from the conditioned medium of the SKG-II-SF cell line derived from a human uterine cervical epidermoid carcinoma. When two-cell stage rat embryos developed into tri-laminal germ disc embryos (flat type), colonies composed of small round cells were isolated by the colonial isolation method and used to establish an ES cell line. The ES cells were cultured in DMEM/F12 medium supplemented with 10% fetal calf serum and 1 ng/mL of leukemia inhibitory factor. Embryoid bodies were made by the hanging-drop method using 1 x 10(7) ES cells/mL. The embryoid bodies differentiated and grew to form an embryonic monster in ETF-supplemented medium using Rose's circumfusion apparatus for about 1 month. The anlages of beating hearts in embryonic monsters were collected using a glass capillary. The anlages were cut into small pieces using razor blades and dissociated with trypsin-EDTA/PBS(-) solution. The resultant single cells were cultured in growth medium and used to establish a myocardial cell line. The cell line was subcultured for more than 25 passages and confirmed as showing the morphological and ultrastructural characteristics of cardiomyocytes.     

Isolation and characterization of embryonic stem-like cells from canine blastocysts

Embryonic stem (ES) cells are pluripotent cells with the capacity to generate any type of cell. Here we describe the isolation of ES-like cells from canine blastocysts. Canine embryos were collected from beagle bitches at day 11-16 of first estrus. A total of 80 normal embryos were obtained from 15 dogs. Of the embryos, 13 were at the morulae stage, 39 at the blastocyst stage, and 28 at the hatched blastocyst stage. The inside of morulae or inner cell masses (ICMs) of blastocysts were isolated mechanically, and cultured onto mouse embryonic fibroblasts (MEF) as feeder layers. Primary cell colonies were formed in 0% (0/13) of morulae, 25.6% (10/39) of blastocysts, and 67.9% (19/28) of hatched blastocysts. These colonies were separated either by enzymatic dissociation or by mechanical disaggregation. Dissociation with collagenase resulted in immediate differentiation, but with mechanical disaggregation these cells remained undifferentiated, and two ES-like cell lines (cES1, cES2) continued to grow in culture after eight passages. These cells had typical stem cell-like morphology and expressed specific markers such as alkaline phosphatase activity, stage specific embryonic antigen-1 and Oct-4. These cells formed embryoid bodies (EBs) in a suspension culture; extended culture of EBs resulted in the formation of cystic EBs. When the simple EBs were cultured on tissue culture plates, they differentiated into several types of cells including neuron-like, epithelium-like, fibroblast-like, melanocyte-like, and myocardium-like cells. These observations indicate that we successfully isolated and characterized canine ES-like cells.     

In vitro differentiation of retinal pigment epithelium from adult retinal stem cells

One of the limitations in molecular and functional studies of the retinal pigment epithelium (RPE) has been the lack of an in vitro system retaining all the features of in vivo RPE cells. Retinal pigment epithelium cell lines do not show characteristics typical of a functional RPE, such as pigmentation and expression of specific markers. The present study was aimed at the development of culture conditions to differentiate, in vitro, retinal stem cells (RSC), derived from the adult ciliary body, into a functional RPE. Retinal stem cells were purified from murine eyes, grown as pigmented neurospheres and induced to differentiate into RPE on an extracellular matrix substrate using specific culture conditions. After 7-15 days of culture, pigmented cells with an epithelial morphology showed a polarized organization and a capacity for phagocytosis. We detected different stages of melanogenesis in cells at 7 days of differentiation, whereas RPE at 15 days contained only mature melanosomes. These data suggest that our protocol to differentiate RPE in vitro can provide a useful model for molecular and functional studies.     

Tumor-Promoting Phorbol Esters Promote Melanogenesis and Prevent Expression of the Adrenergic Phenotype in Quail Neural Crest Cells

Tumor-promoting phorbol esters were used to manipulate the in vitro development of neural crest cells. When plated at clonal density in secondary culture, quail neural crest cells from the trunk region gave rise to three types of colonies, pigmented, unpigmented, and mixed. Pigmented colonies consisted exclusively of melanocytes; up to 50% of the unpigmented and mixed colonies contained adrenergic nerve cells which could be identified by a catecholamine-specific histofluorescence method. Addition of potent tumor promoters to the culture medium shortened the doubling time of neural crest cells and altered their morphologic appearance. It also delayed the onset of pigmentation, prevented the expression of the adrenergic phenotype, reduced the number of unpigmented and mixed colonies, and increased the number of pigmented colonies, most likely by directing progenitor cells preferentially to the melanogenic pathway. There was a clear correlation between the ability of phorbol esters to promote skin tumors in mice and their ability to interfere with the in vitro development of quail neural crest cells. The potent promoters 12–0–tetradecanoyl phorbol 13–acetate (TPA) and phorbol 12,13–didecanoate (PDD) were most effective, phorbol 12,13–diacetate (PDA) was considerably less effective, the nonpromoting analogues 4–0–methyl 12–0–tetradecanoyl phorbol 13–acetate (4–0–Me-TPA) and 4α-phorbol 12,13–didecanoate (4α-PDD) and the parent alcohol phorbol (PHR) had little or no effect.     

Development of smooth and skeletal muscle cells in the iris of the domestic duck,chick and quail

Summary Embryonic development of the avian iris muscle was studied by light and electron microscopy in order to clarify the origin of the iridial skeletal muscle cells. In normal development of the domestic duck, chick, and quail, the muscle bundles appearing in the iris at stage 35 consisted solely of smooth muscle cells. Undifferentiated cells appeared at stage 36, and finally skeletal muscle cells were observed at stage 37. This sequence suggests that stromal mesenchymal cells migrate into the muscle bundles to become skeletal muscle cells.Tissue culture of whole indes removed from duck embryos at stages 30 through 34 produced skeletal muscle cells while culture of isolated iridial epithelia removed at stages 31 and 32 did not. Removal of the midbrain region of duck embryos at stage 10 frequently produced severe disorganization of the eye concomitant with craniofacial deformities typical of a neural crest mesenchymal defect. These severely disorganized eyes were devoid of iridial skeletal muscle cells. These results also suggest mesenchymal origin of iridial skeletal muscle cells.     

Adhesiveness and distribution of vinculin and spectrin in retinal pigmented epithelial cells during growth and differentiation in vitro

Colonies of chick retinal pigmented epithelial (RPE) cells offer an excellent model system for studying the organization of cytoskeleton in sheets of differentiating epithelial cells. The cells occupying the center of the colony resemble RPE cells in vivo and are cuboidal, pigmented, and relatively nonadherent while those toward the periphery gradually become flatter, nonpigmented, motile, and strongly adherent to the substratum. Immunofluorescence microscopy with antiserum against chicken erythrocyte alpha-spectrin reveals that this protein is present in the cortex of RPE cells in all parts of the colony. It is neither concentrated in, nor excluded from the regions occupied by the major microfilament bundles, and its distribution is not related to the adhesion patterns visualized by surface reflection interference microscopy. In contrast, the distribution of vinculin is closely correlated with the adhesiveness of RPE cells in different parts of the colony. Immunofluorescence microscopy reveals that in the RPE cells vinculin may be diffusely distributed in the cytoplasm; present in a cortical band outlining the cell borders; and present in focal contacts and adhesions. The distribution of vinculin is affected by the length of time the colonies grow in culture, by the degree of cell packing and by the adhesiveness of cells to the substratum. In RPE cells grown in vitro for short periods (less than or equal to 3 days) vinculin is found in focal contacts and adhesions in both the undifferentiated, well spread peripheral cells as well as in the differentiated, polygonally packed central cells of the colony. In RPE cells cultured for longer periods (greater than or equal to 14 days) vinculin is present in focal contacts and adhesions only in strongly adherent, undifferentiated cells at the edge of the colony. In packed central cells of both short- and long-term cultures vinculin is found in the cortical band which circumscribes the apical ends of cells at the level of the adherens type intercellular junctions. Its appearance in the cortical bands does not depend on the length of time the colonies are grown in vitro but on the presence of cell-cell contacts resulting from an increased degree of cell packing within the central part of the colony. These results are discussed in relation to the development and the role of extracellular matrix in determining the adhesiveness of RPE cells in vitro.     

Different aggregation properties of sea urchin embryonic cells at different developmental stages. I. Stage specificity of aggregation factors solubilized by butanol

Surface proteins solubilized with butanol from purified plasma membranes of sea urchin embryos at different developmental stages were tested for their aggregation promoting activity on dissociated cells. Cells used for the assays were obtained either from blastulae or from embryos at the 16 cell stage. Results show that a strong enhancement of cell aggregation was produced only when extracted proteins and dissociated cells were obtained from embryos at the same developmental stage.     

Determination of limb bud chondrocytes during a transient block of the cell cycle.

The process of determination is studied by using a cell culture system derived from dissociated chick embryo limb buds. When limb bud cells obtained from embryos younger than stage 25 (undertermined) are temporarily prevented from passing through the cell cycle (either by maintaining the cells on a petri dish or in the presence of high concentrations of cyclic AMP, both of which depress thymidine-H(3) incorporation), some cells subsequently form cartilage colonies. These results support the hypothesis that a temporary block at some stage in the cell cycle causes mesoblasts to acquire the capacity to differentiate into cartilage cells.     

Ultrastructural study on the retinal pigment epithelium of human embryos, with special reference to quantitative study on the development of melanin granules

The development of the retinal pigment epithelium (RPE) was studied ultrastructurally, using 13 externally normal human embryos, Carnegie stages ranging from 13 to 23 (4-8 week of gestation). Melanosomes in the peripheral and posterior RPE were classified according to Fitzpatrick et al. The melanosome of phase I is formed from the Golgi complex and parcelled off into small vesicles. The vesicle enlarges and elongates to form an oval organelle with membranous structures in it (phase II melanosome). Subsequently, melanin deposits on the membranous structures of the melanosomes (phase III melanosomes), and the completion of this process produces a uniformly electrondense granule without discernible internal structures (phase IV melanosome). Melanosomes of phases III and IV appeared in the RPE at stage 15. As the embryonic stage advanced, the ratio of phase II melanosomes decreased and that of phase IV melanosomes increased. The number of phase III melanosomes reached a peak in the peripheral and posterior RPE at stages 15 and 18, respectively. After stage 17, the increase in melanosomes and intracellular organelles was more prominent in the posterior than in the peripheral RPE. During stages 13 and 15, gap junctions were present not only in the apical but also basal plasma membranes of the RPE. At stage 20, gap junctions in the basal plasma membrane disappeared except for the transitional areas from the RPE to the neural retina (NR). In addition, gap junctions were observed between NR and RPE only in the peripheral region at stage 20. The morphological and quantitative differences in the peripheral and posterior RPE in the embryonic period are discussed.     

Different aggregation properties of sea urchin embryonic cells at different developmental stages. II. Stage specific response to fibronectin and collagen

Fibronectin and collagen were added to cells dissociated from embryos at the blastula and at the 16 cell stages. Both molecules stimulate aggregation of cells dissociated from blastula but they do not affect aggregation of blastomeres dissociated from the 16 cell stage. The stage-specific response to fibronectin and collagen appears to be related to the onset of new functional role(s) of the two molecules at the blastula stage.     

Polarization of blastomeres in the cleaving rabbit embryo

Cellular polarization is believed to be a crucial event in the differentiative divergence of the two cell lineages leading to the blastocyst in rodent embryos. This study was undertaken to determine if rabbit embryos exhibited cellular polarization prior to blastocyst formation and to define the embryonic stage at which polarization was first apparent. Polarity was assayed by observation of the pattern of binding of FITC-Con A to dissociated blastomeres from three stages of rabbit embryos. Scanning electron microscopy on the dissociated cells confirmed the fluorescence results. Fifty-one percent of blastomeres in 38- to 66-cell rabbit embryos exhibited an intense pole of FITC-Con A binding and a single pole of microvilli. Only 2% of blastomeres at the 17- to 34-cell stage were similarly polarized and none were polarized at the 8- to 16-cell stage. In addition, during attempts to remove the mucin coat and zona pellucida from the rabbit embryos prior to their dissociation, it was found that the protease sensitivity of these coats also changed at the 38- to 66-cell stage. Prior to this time, although the mucin coat disappeared after 30 min in 0.5% pronase, the zona required approximately 1.5-2.5 hr in pronase for even partial removal. At the 38- to 66-cell stage, pronase dissolved the mucin coat within 10 min and the zona pellucida within 20 min. The zona was resistant to 0.1% proteinase K at all stages examined.     

Cultivation and Differentiation of Dissociated Cells of Chick Embryo Encephalon

Dissociated cells from cerebral hemispheres of chick embryo at stages 17–18, 12–13 and 9–10, were cultivated for seven days. The cells were cultivated either completely covered with the nutrient medium in an atmosphere containing 5 percent CO₂ or they were covered by only a thin film of nutrient medium in contact with air.
For the embryos at stages 17–18 or 12–13, under both culture conditions neurons differentiated after 3 or 4 days in culture, while for the embryos at stage 9–10, no neuronal differentiation occurred under either condition. The cells remained morphologically undifferentiated and formed aggregates of about 50 cells. Some fibroblasts were found to grow on the collagen matrix.
It is concluded that dissociated cells from embryos at stage 9–10 are incapable of auto differentiation under the present culture conditions. The possible causes of this inability to differentiate are discussed.     

Note on differentiation of the epithelium of the small intestine in human embryos

We studied the development of the human embryonic intestine from the 6th to the 8th week of gestation (embryos with a crown-rump length of 16-25 mm). Semithin sections show that a smooth, simple intestinal lumen, which is often a mere slit, is elsewhere, in the same specimen, distinctly formed and in places is partly occluded by accumulations of cells of a somewhat different character from those of the actual intestinal lining. Whereas the epithelium proper is mainly high and pseudostratified, the cells which secondarily occlude the originally open intestinal lumen are smaller and are more cuboidal to polyhedric in shape. In the electron microscope, the cells of the primitive epithelium appear narrow and columnar, with an ovoid nucleus and a few nucleoli. The cytoplasm contains numerous mitochondria and a gradually developing granular endoplasmic reticulum and Golgi complex. These cells have small, irregular microvilli on their surface, but some have an almost straight surface without any microvilli. They display striking pinocytotic activity and contain a quantity of multivesicular bodies. Their cytoplasm further contains isolated osmiophilic granules and lysosomes and a small amount of glycogen. The accumulation of glycogen is typical of the more mature developmental stages. Cilia are a characteristic finding in embryos with a c-r length of 16-25 mm. There is only one cilium to a cell, but not all the cells have cilia. The cilia are relatively thick and not very long and they almost always grow in the centre of the cell surface. The apical surface of such cells is usually slightly or more deeply concave. Structurally, the ciliated cells closely resemble phylogenetically primitive entodermal collar cells (choanocytes). They are apparently a phylogenetically old type of cells, whose existence could have functional value, which appears for a time during ontogenetic development. The cilia may temporarily play a role in the movement of the intestinal fluid and thus coparticipate in resorption before the musculature of the intestinal wall has been formed.