Differentiation of Rat Lens Epithelial Cells in Tissue Culture

The growth and differentiation of rat lens epithelial cells in tissue culture were studied. Cells could be maintained for a number of generations in an undifferentiated state in suspension culture. When cultured as monolayers, they grew and differentiated in a series of six defined stages described here. These stages include morphological changes (elongation, followed by cell "spreading" or formation of cell aggregates), and biochemical changes (appearance of y-crystallin protein as detected by immunofluorescence). The process of differentiation appeared to be accelerated in the vicinity of elongated cells, occurred more rapidly at high cell density, and required frequent changes of medium. This suggests that cell-cell communication, and not medium factors, may be essential for promoting differentiation. The final morphology of the differentiated cells differed, depending on the embryonic age of the rats used as a source of lens epithelial cells. This implies that the programme for differentiation changes as a function of the embryonic age of the lens.     

Dedifferentiation of lens epithelial cells in tissue culture

Lens epithelial cells can be kept in their original differentiated state or brought to dedifferentiation depending on the culture conditions. The different stages of differentiation can be identified using specific markers, namely the activity of steroid metabolizing enzymes, and the synthesis of specific structural lens polypeptides. For this reason lens epithelial cells in tissue culture provide a unique system for the study of the regulation of RNA and protein biosynthesis.Abbreviations dehydroepiandrosterone (DHEA)= 3-hydroxy-5-androsten-17-one - androstenediol (ADIOL)= 5-androstene-3, 17-diol - androstenedione(ADION)= 4-androstene-3, 17-dione     

Differentiation of isolated murine embryonic palatal epithelium in culture: exogenous transforming growth factor alpha modulates matrix biosynthesis in defined experimental conditions

Summary A novel culture technique, which supports the growth and differentiation of mouse embryonic palatal epithelial cells in the absence of either an extracellular matrix substratum or feeder layers, has been developed. Using this technique we have investigated the effects of exogenous transforming growth factor alpha (TGFα) and serum on extracellular matrix biosynthesis by primary cultures of mouse embryonic epithelial sheets under defined experimental conditions. In all culture treatments (chemically defined medium with and without TGFα or serum) the palatal epithelial sheets differentiated into three regionally distinct cell phenotypes after 36 h. Nasal and oral cells differentiated into pseudostratified, cilliated columnar, and stratified squamous keratinizing epithelium, respectively. In addition, basal medial edge epithelial (MEE) cells at the oral/nasal regional interface assumed an elongated cobblestoned phenotype. In serum-free medium, collagen types IV and V, laminin, fibronectin, and heparan sulphate proteoglycan were detected immunocytochemically throughout the entire epithelial sheet. Tenascin and collagen IX were present almost exclusively in MEE cells. Types I, II, and III collagen were completely absent. Addition of TGFα or serum universally increased the intensity of staining, most notably that for tenascin and collagen IX in MEE cells. These results indicate that mouse embryonic palatal epithelial sheets can be maintained under defined culture conditions during which they exhibit patterns of differentiation similar to those observed in vivo. TGFα, known to localize to the MEE in vivo, can modulate palatal extracellular matrix biosynthesis, particularly by the MEE, suggesting a regulatory role for this factor. The culture system is suitable for further investigating the effects of exogenous factors on mouse embryonic palatal epithelial cell bioactivity and differentiation.     

alpha6 Integrin is regulated with lens cell differentiation by linkage to the cytoskeleton and isoform switching.

The developing chicken embryo lens provides a unique model for examining the relationship between alpha6 integrin expression and cell differentiation, since multiple stages of differentiation are expressed concurrently at one stage of development. We demonstrate that alpha6 integrin is likely to mediate the inductive effects of laminin on lens differentiation as well as to function in a matrix-independent manner along the cell-cell interfaces of the differentiating cortical lens fiber cells. Both alpha6 isoform expression and its linkage to the cytoskeleton were regulated in a differentiation-specific manner. The association of alpha6 integrin with the Triton-insoluble cytoskeleton increased as the lens cells differentiated, reaching its highest levels in the cortical fiber region where the lens fiber cells are formed. In this region of the lens alpha6 integrin was uniquely localized along the cell-cell borders of the differentiating fiber cells, similar to beta1. alpha6beta4, the primary transmembrane protein of hemidesmosomes, is also expressed in the lens, but in the absence of hemidesmosomes. Differential expression of alpha6A and alpha6B isoforms with lens cell differentiation was seen at both the mRNA and the protein levels. RT-PCR studies demonstrated that alpha6B was the predominant isoform expressed both early in development, embryonic day 4, and in the epithelial regions of the day 10 embryonic lens. Isoform switching, with alpha6A now the predominant isoform, occurred in the fiber cell zones. Immunoprecipitation studies showed that alpha6B, which is characteristic of undifferentiated cells, was expressed by the lens epithelial cells but was dramatically reduced in the lens fiber zones. Expression of alpha6B began to drop as the cells initiated their differentiation and then dropped precipitously in the cortical fiber zone. In contrast, expression of the alpha6A isoform remained high until the cells became terminally differentiated. alpha6A was the predominant isoform expressed in the cortical fiber region. The down-regulation of alpha6B relative to alpha6A provides a developmental switch in the process of lens fiber cell differentiation.     

The influence of culture media on embryonic renal collecting duct cell differentiation

Summary During kidney development the embryonic ampullar collecting duct (CD) epithelium changes its function. The capability for nephron induction is lost and the epithelium develops into a heterogeneously composed epithelium consisting of principal and intercalated cells. Part of this development can be mimicked under in vitro conditions, when embryonic collecting duct epithelia are isolated from neonatal rabbit kidneys and kept under perfusion culture. The differentiation pattern is quite different when the embryonic collecting duct epithelia are cultured in standard Iscove’s modified Dulbecco’s medium as compared to medium supplemented with additional NaCl. Thus, the differentiation behavior of embryonic CD epithelia is unexpectedly sensitive. To obtain more information about how much influence the medium has on cell differentiation, we tested medium 199, basal medium Eagle, Williams’ medium E, McCoys 5A medium, and Dulbecco’s modified Eagle medium under serum-free conditions. The experiments show that in general, all of the tested media are suitable for culturing embryonic collecting duct epithelia. According to morphological criteria, there is no difference in morphological epithelial cell preservation. The immunohistochemical data reveal two groups of expressed antigens. Constitutively expressed antigens such as cytokeratin 19, P_CD 9, Na/K ATPase, and laminin are present in all cells of the epithelia independent of the culture media used. In contrast, a group of antigens detected by mab 703, mab 503, and PNA is found only in individual series. Thus, each culture medium produces epithelia with a very specific cell differentiation pattern.     

Maintenance of the synthesis of alpha B-crystallin and progressive expression of beta Bp-crystallin in human fetal lens epithelial cells in culture

We have cultured and maintained human fetal lens epithelial cells for several months in primary, secondary, and tertiary culture(s). These cells show unabated synthesis of alpha B-crystallin (alpha B), a lens epithelial cell-specific marker, and progressive expression of beta Bp-crystallin (beta Bp), a major polypeptide of the differentiated lens fiber cells in vivo. Interestingly, the expression of beta Bp was found to be dependent on subculturing of the cells and not on the age of cultures. These observations demonstrate that human fetal lens epithelial cells can be cultured in vitro without the loss of lens specific characteristics and with commitment to differentiation at the biochemical level.     

Influence of epidermal growth factor and cyclic AMP on growth and differentiation of palatal epithelial cells in culture

A serum-free, hormonally defined medium was developed which supports growth and differentiation in primary culture of epithelial cells from prefusion embryonic mouse palatal shelves. Using this culture system, medial epithelial programmed cell death was investigated. In the absence of EGF, medial epithelial cells undergo cell death and detach from the substratum by 24 hr of culture. The addition of EGF alone or in combination with various agents which increase intracellular cyclic AMP levels prevented medial epithelial cell death in both cell and organ culture. EGF appeared to exert its most dramatic effect in cell culture on growth and differentiation of the squamous oral epithelial cells. In addition, EGF and agents such as 8-bromo-cyclic AMP, dibutyryl cyclic AMP, or cholera toxin synergistically stimulated the appearance of a long-lived, rapidly proliferating cell type by Day 4 of culture. Our results suggest that both EGF and cyclic AMP together may be important in regulating proliferation of embryonic palatal epithelial cells.     

Insulin and IGF receptors are developmentally regulated in the chick embryo eye lens

We have previously reported that insulin-like growth factor (IGF) receptors appear to predominate over insulin receptors in early stages of embryogenesis in the chick (days 2-3 whole embryo membranes). Overall, [125I]IGF I and II binding to specific receptors was maximal when the rate of brain growth is highest. In the present study we used the embryonic chick lens, a well-defined tissue composed of a single type of cell, to analyse whether changes of insulin and IGF I binding are correlated with changes in growth rate and differentiation state of the cells. We show that both insulin receptors and IGF receptors are present in the lens epithelial cells, and that each type is distinctly regulated throughout development. While there is a direct correlation between IGF-binding capability and growth rate of the cells, there is less relation to differentiation status and embryo age. Insulin receptors, by contrast, appear to be mostly related to the differentiated state of cells, decreasing sharply in fibers, irrespective of their developmental age.     

In vitro analysis of cellular metaplasia from pigmented epithelial cells to lens phenotypes: a unique model system for studying cellular and molecular mechanisms of "transdifferentiation"

Pigmented epithelial cells (PECs) were dissociated from eyes of 8- to 9-day-old chick embryos and were cultured in EdF medium (Eagle's MEM supplemented with dialyzed fetal bovine serum) containing phenylthiourea (PTU) and testicular hyaluronidase (HUase). The PECs rapidly lost melanosomes as they proliferated and dedifferentiated in culture. These dedifferentiated PECs (dePECs) which did not manifest any identifiable specificity could be directed to one of two different differentiated phenotypes; viz., lens or pigment cells, depending upon subsequent culture conditions. Almost all dePECs began to synthesize melanin and redifferentiated to PECs by Day 10 of culture with EdF medium containing ascorbic acid (AsA). In contrast, the sister population of dePECs, when cultured at extremely high cell density with EdF medium containing PTU, HUase and AsA, synthesized delta-crystallin which is specific for lens. This transdifferentiation into lens cells occurred by Day 15 of culture. Using this culture system we are able to produce a homogeneous cell population with the potential for synchronous differentiation into either lens or pigment cell phenotype. The system is useful for studying mechanisms involved in cellular metaplasia.     

Decreased turnover of phosphatidylinositol accompanies in vitro differentiation of embryonic chicken lens epithelial cells into lens fibers

The in vivo differentiation of embryonic chicken lens epithelial cells into lens fibers is accompanied by a marked decrease in the rate of degradation of phosphatidylinositol. The present experiments were undertaken to determine whether a similar change in phosphatidylinositol metabolism occurs during in vitro lens fiber formation in cultured explants of embryonic chicken lens epithelia. Lens epithelial cells in the explants differentiate into lens fibers following the addition of fetal calf serum, insulin or chicken vitreous humor to the culture medium. The results show that phosphatidylinositol is degraded with a half-life of 3-6 h in cultured lens epithelia that are not stimulated to differentiate. In contrast, no degradation occurs for at least 6 h in lens epithelia stimulated to form lens fibers. The stabilization of phosphatidylinositol is apparent within 4 h after the onset of fiber cell formation, and thus represents an early event in differentiation. The rapid degradation of phosphatidylinositol in lens epithelia is accompanied by comparably rapid synthesis. During this metabolic turnover only the phosphorylinositol portion of the molecule is renewed, as expected if hydrolysis occurs by the action of a phospholipase C, such as phosphatidylinositol phosphodiesterase. Thus, these data suggest that agents which produce in vitro differentiation of embryonic chicken lens epithelial cells into lens fibers lead to a reduction in either the amount or the activity of phospholipase C.     

Wnt signaling enhances FGF2-triggered lens fiber cell differentiation

Wnt signaling is implicated in many developmental processes, including cell fate changes. Several members of the Wnt family, as well as other molecules involved in Wnt signaling, including Frizzled receptors, LDL-related protein co-receptors, members of the Dishevelled and Dickkopf families, are known to be expressed in the lens during embryonic or postembryonic development. However, the function of Wnt signaling in lens fiber differentiation remains unknown. Here, we show that GSK-3beta kinase is inactivated and that beta-catenin accumulates during the early stages of lens fiber cell differentiation. In an explant culture system, Wnt conditioned medium (CM) induced the accumulation of beta-crystallin, a marker of fiber cell differentiation, without changing cell shape. In contrast, epithelial cells stimulated with Wnt after priming with FGF elongated, accumulated beta-crystallin, aquaporin-0, p57kip2, and altered their expression of cadherins. Treatment with lithium, which stabilizes beta-catenin, induced the accumulation of beta-crystallin, but explants treated with lithium after FGF priming did not elongate as they did after Wnt application. These results show that Wnts promote the morphological aspects of fiber cell differentiation in a process that requires FGF signaling, but is independent of beta-catenin. Wnt signaling may play an important role in lens epithelial-to-fiber differentiation.     

Chicken embryo lens cultures mimic differentiation in the lens

Embryonic chicken lenses, which had been disrupted by trypsin, were grown in culture. These cultures mimic lens development as it occurred in vivo, forming lens-like structures known as lentoids. Using a variety of techniques including electron microscopic analysis, autoradiography, immunofluorescence, and polyacrylamide gel electrophoresis, it was shown that the lentoid cells had many characteristics in common with the differentiated cells of the intact lens, the elongated fiber cells. These characteristics included a shut off of DNA synthesis, a loss of cell organelles, an increase in cell volume, an increase in δ-crystallin protein, and the development of extensive intercellular junctions. The cultures began as a simple epithelial monolayer but then underwent extensive morphogenesis as they differentiated. This morphogenesis involved three distinctive morphological types which appeared in sequence as an epithelial monolayer of polygonal shaped cells with pavement packing, elongated cells oriented end to end, and the multilayered, multicellular lentoids. These distinct morphological stages of differentiation in culture mimic morphogenesis as it occurs in the lens.     

The retention of differentiated properties by lens epithelial cells in clonal cell culture

A small number of cells of lens epithelium from newly hatched chickens were cultured at clonal density to investigate the retention of differentiated properties during cellular growth in vitro. Singly plated cells proliferated to produce colonies, at least some of which were considered to be true clones of single cell origin. The differentiation of lens fibers occurring in many colonies was identified through observations by electron microscopy as well as immunofluorescence utilizing specific antiserum against lens fibers. Primary or secondary mass cultures of cells of lens epithelium contained cells which produce differentiated colonies when cultured at clonal density. Colony-producing cells can be differentially dissociated from monolayers by EDTA treatment without using tyrpsin. For successful culture of cells of lens epithelium at clonal density, the use of conditioned medium is necessary.     

Anchorage-independent culture maintains prostate stem cells

Freshly isolated mouse prostate epithelial cells regenerate fully differentiated prostate tissue when combined with embryonic urogenital sinus mesenchyme and grafted in vivo. We show here that this regenerative capacity, which has been attributed to a small population of pleuripotential progenitor epithelial cells, is rapidly lost when the cells are placed in monolayer culture but can be maintained by culture in anchorage-independent conditions. Epithelial cells placed in anchorage-independent culture formed proliferating spheres that could be serially passaged and exhibited increased expression of putative stem cell markers as compared to cells grown in monolayer culture. Epithelial cells isolated from the fetal urogenital sinus, the newborn, and adult prostate formed spheres with similar efficiency, while cells isolated from the post-castration prostate exhibited significantly higher sphere-forming abilities. When passaged spheres were recombined with E17 rat urogenital sinus mesenchyme and grafted in vivo, they generated fully differentiated mouse prostate glandular epithelium containing both p63+ basal cells and p63− luminal cells and expressing a variety of prostate-specific and terminal differentiation markers.     

Activin and follicle-stimulating hormone signaling are required for long-term culture of functionally differentiated primary granulosa cells from the chicken ovary

Follicle-stimulating hormone, activin A, and transforming growth factor (TGF) alpha are important regulators of chicken granulosa cell (cGC) function. Hence, we aimed to test whether these growth factors are useful for establishing a suitable in vitro cell culture model system of primary cGC. Although cGC are easily isolated from distinct follicular stages, a long-term cGC culture system for in vitro studies has been unavailable. Here, we report a novel, long-term cell culture system that allows for cGC proliferation in vitro while maintaining the epithelial phenotype that granulosa cells exhibit in vivo. The cGC rapidly lose their epithelial morphology and acquire a mesenchymal or fibroblastoid phenotype when cultured in the absence of activin A. This process is strongly enhanced by TGFalpha, a well-known granulosa cell mitogen. However, FSH stimulates cGC proliferation without enhancing morphological changes and dedifferentiation. Interestingly, a combination of both activin A and FSH stimulates cGC proliferation and supports maintenance of differentiated epithelial morphology. Furthermore, activin A and FSH synergistically induce granulosa cell-specific differentiation markers such as inhibin alpha and chicken zona pellucida protein C, suggesting that cultured cGC resemble functionally differentiated granulosa cells. Our data demonstrate that activin signaling is necessary to sustain a morphologically differentiated phenotype of cGC in vitro. The results also suggest a pivotal importance of activin signaling for granulosa cell function in vivo.     

Identification and differentiation of lens cells in tissue culture]

The cells of S-phase labelled prior to cultivation with H3-thymidine and other neighbouring cambial cells of the lens of the pig, cattle and sheep were found to form morphologically underdifferentiated zones of growth. The zones of growth were formed in the culture from differentiating in vivo cells of the lens. The cells of these zones occasionally resembled abortively differentiated lens fibres in vivo. The growth zones of the lens cells in vitro are comparable by its growings in trauma or cataract in vivo. In lens cultures under routine conditions of cultivation there occurs disturbance of normal embryonic histogenesis and abortive differentiation of the already differentiated in vivo cells.     

Volume regulation in lens epithelial cells and differentiating lens fiber cells

Previous studies from our laboratory have led us to conclude that lens cell elongation is caused by an increase in cell volume. This volume increase results from an increase in the potassium content of the cells due to decreased potassium efflux. In contrast, an increase in the volume of most cells triggers a regulatory volume decrease (RVD) that is usually mediated by increased potassium efflux. For this reason, chicken embryo lens epithelial cells were tested to see whether they were capable of typical cell volume regulation. Changes in cell volume during lens fiber differentiation were first estimated by 3H2O water uptake. Cell water increased in proportion to cell length in elongating lens cells. Treatment of epithelial cells cultured in basal medium with dilute or concentrated medium, or with medium containing 50 mM sucrose, resulted in typical volume regulatory responses. Cells lost or gained volume in response to osmotic stress, then returned to their previous volume. In addition, the elongation and increase in cell volume that accompanies lens fiber cell differentiation occurred normally in either hypo- or hypertonic media. This observation showed that the activation of mechanisms to compensate for osmotic stress did not interfere with the increase in volume that accompanies elongation. The ability of elongating cells to volume regulate was also tested. Lens epithelial cells were stimulated to elongate by exposure to embryonic vitreous humor, then challenged with hypotonic medium. These elongating cells regulated their volume as effectively as unstimulated cells. Therefore, cells that were increasing their volume due to reduced potassium efflux could adjust their volume in response to osmotic stress, presumably by increasing potassium efflux. This suggests that the changes in potassium efflux that occur during differentiation and RVD are regulated by distinct mechanisms.