Stimulation of the Clonal Growth and Differentiation of Feeder Layer Dependent Mouse Embryonal Carcinoma Cells by β-Mercaptoethanol

Embryonal carcinoma cells are the undetermined stem cells of teratocarcinomas. Supplementation of culture medium with β-mercaptoethanol permits the feeder layer independent clonal growth and differentiation of normally feeder layer dependent embryonal carcinoma cell lines. Differentiated cells within the clones appeared less than 6 days after plating and were distinguished from embryonal carcinoma cells by their morphology, lack of histochemically detectable alkaline phosphatase activity, and secretion of plasminogen activator. Over 70% of the colonies secreted plasminogen activator after 6 days.
In comparison, a different embryonal carcinoma cell line which has lost the potential for substantial differentiation, either in vitro or in vivo forms very few clones (< 1%) which secrete plasminogen activator. Embryonal carcinoma cells derived from the rare clones which secrete plasminogen activator have the same frequency of production of plasminogen activator secreting colonies as the parental cell line.     

Assessment of pluripotency and multilineage differentiation potential of NTERA-2 cells as a model for studying human embryonic stem cells

Embryonal carcinoma cells are pluripotent stem cells derived from teratocarcinomas and are considered to be the malignant counterparts of human embryonic stem cells. As there are few reliable experimental systems available to study the molecular mechanisms governing normal embryogenesis, well-characterized human embryonal carcinoma stem cell lines may provide a robust and simple model to study certain aspects of pluripotency and cellular differentiation. Here, we have analysed NTERA-2 cL.D1 cells at molecular and cellular levels during expansion and differentiation, via formation of cell aggregates similar to embryoid bodies in embryonic stem cells. Thus, human embryonal carcinoma cells may provide a valuable insight into cell fate determination, into the embryonic ectoderm, mesoderm and endoderm and their downstream derivatives.     

Isolation and characterization of a multipotent clone of human embryonal carcinoma cells

Histopathological studies suggest that the stem cells of human teratomas may be classified into two major categories: nullipotent stem cells, and multipotent stem cells, capable both of self-renewal and differentiation into a wide range of somatic and extraembryonic cell types. We have isolated a multipotent stem cell clone from the human teratoma cell line GCT 27, and compared its properties to a nullipotent clone derived from the same strain. The multipotent clone GCT 27 X-1 gave rise to colonies of mixed cell morphology in vitro. Analysis of cell surface, cytostructural and extracellular matrix markers in GCT 27 X-1 cells showed that the stem cells of this line were very similar in phenotype to nullipotent cells. The two cell clones were predominantly hypotriploid, and contained several marker chromosomes in common. GCT 27 X-1 was feeder-cell-dependent for continuous growth in vitro; removal of the feeder layer resulted in differentiation of the stem cells into a variety of cell types, some with characteristics of extraembryonic endoderm, others showing neuronal properties. When transplanted into nude mice, GCT 27 X-1 cells gave rise to teratocarcinomas containing embryonal carcinoma stem cells, and many other cell types: yolk sac carcinoma cells; cells producing alphafetoprotein or human chorionic gonadotrophin; glandular, columnar, cuboidal, and squamous epithelium; primitive mesenchyme and cartilage; neuroectodermal cells. Nullipotent GCT 27 C-1 cells could form colonies in the absence of feeder layers, but multipotent GCT 27 X-1 cells could not. While a range of known growth factors and related substances failed to substitute for feeder layers in supporting the growth of GCT 27 X-1 stem cells, supernatants from yolk sac carcinoma cell line GCT 44 could partially replace the feeder cell requirement. Thus, the results revealed a basic difference in growth control between these multipotent and nullipotent human embryonal carcinoma cells, and suggested a possible paracrine regulatory pathway between multipotent stem cells and yolk sac carcinoma cells.     

Flow Cytoenzymology of the Early Differentiation of Mouse Embryonal Carcinoma Cells

Dual parameter flow cytoenzymology was used to detect biochemical differentiation of embryonal carcinoma cells, the undifferentiated, multipotent stem cells of teratocarcinomas. With the use of fluorogenic substrates, two enzyme systems, alkaline phosphatase (EC 3.1.3.1.) and carboxyl esterase (EC 3.1.1.), were studied. Embryonal carcinoma cells passaged in vitro for several years retained high alkaline phosphatase activities similar to those of embryonal carcinoma cells in embryoid bodies grown in vivo. Similar to the embryonal carcinoma cells in vivo, the in vitro embryonal carcinoma cells were capable of giving rise to progeny with greatly decreased levels of alkaline phosphatase. The embryonal carcinoma cell alkaline phosphatase was inhibited by l-p-bromotetramisole, suggesting a relationship between this enzyme and somatic, nonintestinal alkaline phosphatase isoenzymes. Determinations of esterase activities in viable teratocarcinoma cells showed that prior to any evidence of morphologic differentiation, the embryonal carcinoma cells are quite heterogeneous with regard to esterase activities.     

Action potentials recorded intracellularly from differentiated mouse teratocarcinoma cells in culture

Under appropriate in vitro culture conditions, mouse embryonal carcinoma can give rise to a variety of differentiated cell types, including those having the morphology of nerve cells. We report here that it is possible to evoke from such cells potential changes resembling classical neuronal action potentials, thereby indicating functional differentiation of the malignant stem cell.     

The induction of differentiation in teratocarcinoma stem cells by retinoic acid.

Embryonal carcinoma cells, the stem cells of teratocarcinomas, usually undergo extensive differentiation in vivo and in vitro to a wide variety of cell types. There exist, however, several embryonal carcinoma cell lines that have almost completely lost the capacity to differentiate, so that the cells are propagated primarily as the stem cells. Using one such cell line, F9, we have found that retinoic acid at concentrations as low as 10(-9) M induces multiple phenotypic changes in the cultures in vitro. These changes include morphological alteration at the resolution of the light microscope, elevated levels of plasminogen activator production, sensitivity to cyclic AMP compounds and increased synthesis of collagen-like proteins. The nature of these changes, as well as their independence of the continued presence of retinoic acid, are consistent with the proposition that retinoic acid induces differentiation of embryonal carcinoma cells into endoderm.     

Studies on the activity of the X chromosomes in female teratocarcinoma cells in culture

Embryonal carcinoma cells derived from murine teratocarcinomas are able to differentiate into the same variety of tissue types as early embryonic cells. Because embryonal carcinoma cells resemble those of the embryo at a stage before X chromosome inactivation has occurred in females embyronal carcinoma cells containing two X chromosomes were examined to determine whether both are genetically active. The specific activities of X-linked enzymes were measured in embryonal carcinoma cells containing either one or two X chromosomes. The activities in both cell types were similar, suggesting that only one X chromosome was active in the female cells. Further support for this conclusion came from experiments in which azaguanine-resistant mutants were recovered with similar frequencies from embryonal carcinoma cell lines containing one and two X chromosomes. Late replication of an X chromosome DNA was detected in one embryonal carcinoma cell line with two X chromosomes but not in another. This suggests that cells of these two lines were arrested at different developmental stages, and that late DNA replication may not be a necessary adjunct of X inactivation. Evidence is presented which suggests that X chromosome reactivation does not occur during differentiation of the cells in vitro.     

alpha-Difluoromethylornithine induces differentiation of a human embryonal carcinoma cell line in vitro

Human embryonal carcinoma cells could serve as a useful model system for analysis of early human development. A limited number of human embryonal carcinoma cell lines have been generated from in vivo tumors. We report here that alpha-difluoromethylornithine, a specific enzyme-activated inhibitor of ornithine decarboxylase activity, can induce differentiation in human embryonal carcinoma cells. The differentiated phenotype could be distinguished from undifferentiated cells by altered cellular morphology, biochemical and cell surface antigenic properties. These results suggest that alterations in the intracellular levels of polyamines may play a role in human embryonal carcinoma cell differentiation, and possibly human embryogenesis.     

The response of embryonal carcinoma cells to retinoic acid depends on colony size

Single cells of the feeder-layer-dependent mouse embryonal carcinoma (EC) cell line, NG2, can spontaneously give rise to colonies containing a wide variety of differentiated cell types in vitro. When cultured with retinoic acid at a concentration of 10(-7) M, single NG2 cells irreversibly differentiated to parietal endoderm, as identified by morphological criteria and immunohistochemical staining. Parietal endoderm was also the first product of spontaneous differentiation. However, when retinoic acid was added to monolayer groups of NG2 cells, not all of the cells were induced to differentiate. The parietal-endoderm cells which did form were generally found at the periphery of cell colonies, as is the case during spontaneous differentiation. Differentiation in the centre of these colonies yielded a variety of cell types over a 21-day period. These results are consistent with the hypothesis that retinoic acid induces the differentiation of EC cells by accelerating cellular response to intrinsic stimuli, rather than by overriding these stimuli.     

Turning germ cells into stem cells

Primordial germ cells (PGCs), the embryonic precursors of the gametes of the adult animal, can give rise to two types of pluripotent stem cells. In vivo, PGCs can give rise to embryonal carcinoma cells, the pluripotent stem cells of testicular tumors. Cultured PGCs exposed to a specific cocktail of growth factors give rise to embryonic germ cells, pluripotent stem cells that can contribute to all the lineages of chimeric embryos including the germline. The conversion of PGCs into pluripotent stem cells is a remarkably similar process to nuclear reprogramming in which a somatic nucleus is reprogrammed in the egg cytoplasm. Understanding the genetics of embryonal carcinoma cell formation and the growth factor signaling pathways controlling embryonic germ cell derivation could tell us much about the molecular controls on developmental potency in mammals.     

Regulation of phenotype in somatic cell hybrids derived by fusion of teratocarcinoma cell lines with normal or tumor-derived mouse cells

The phenotypes of somatic cell hybrids between murine embryonal carcinoma cell lines, F9 BrdU 7C12 and PCC4 aza 1, and normal murine splenic lymphocytes or thymoma-derived cell lines were compared. Analysis of morphology in vivo and in vitro of cell surface markers and of the karyotype of these cloned hybrid cells did not reveal any simple mechanism for the regulation of the phenotype of such hybrids. Hybrids of either the embryonal carcinoma cell phenotype or of a differentiated morphology (resembling neither parental cell) but not of lymphoid morphology can be derived from fusions of this type. Moreover, transition from one phenotype to the other (ECC → differentiated cell and differentiated cell → ECC) can be found with passage of clonally derived hybrid cell lines. Coordinate control of the phenotypic markers of the state of differentiation in these hybrid cells was found.     

Inhibition of ornithine decarboxylase induces embryonal carcinoma cell differentiation

Murine embryonal carcinoma cells can be induced to differentiate in vitro by various physical and chemical means. We report here that inhibition of ornithine decarboxylase activity with a specific enzyme-activated inhibitor, alpha-difluoromethylornithine, can induce differentiation in embryonal carcinoma cells. The differentiated phenotype can be distinguished from undifferentiated embryonal carcinoma cells by altered cellular morphology, biochemical and cell surface antigenic properties. These results suggest that alterations in the levels of cellular polyamines may play a role in embryonal carcinoma cell differentiation.     

Pluripotent Embryonal Stem Cell Lines Can Be Established from Disaggregated Mouse Morulae

Mouse pluripotent embryonal stem ( ES ) cell lines hitherto have been conventionally isolated from the 'inner cell mass' of mouse blastocysts. In this report, I describe a new and simplified method for establishing pluripotent cell lines from mouse morulae of the 16- to 20-cell stage, which were disaggregated by the use of EDTA. From 17 cell lines established in such a way, 7 were characterized with respect to their differentiation potential:
(i) When injected into syngeneic mice, the cells gave rise to solid, fully differentiated teratomas representing derivatives of all three germ layers. (ii) When cultured in suspension in vitro, the cells were able to differentiate into complex organized 'embryoid bodies' analogous to mouse early postimplantation embryos. These results strongly imply that embryonal stem cell lines isolated from mouse morulae are highly homologous to conventionally isolated ES cells.
In addition, my results indicate that murine pluripotent embryonal stem ( ES ) cell lines can be derived with more ease and higher efficiency from disaggregated morulae than from the 'inner cell mass' of blastocysts.     

Analysis of the differentiation-promoting potential of inducible c-fos genes introduced into embryonal carcinoma cells.

To investigate the differentiation-promoting potential of c-fos in embryonal carcinoma cells (EC cells) we have designed various human metallothionein promoter-mouse-c-fos gene constructs containing also the selectable SV40 promoter-driven neo gene. Upon transfection into F9 EC cells and selection for neo resistance, the following results were obtained. (i) With each of the constructs, colonies of morphologically altered and differentiated (i.e., TROMA-1 and TROMA-3 expressing) cells were identified. (ii) Expression of c-fos was required to affect the differentiation state of F9 cells to a significant extent, but a low level was sufficient; no enhancement of differentiation was noticeable even after 100-fold induction of c-fos expression by cadmium. (iii) F9 cell clones were isolated which, in spite of very high levels of exogenous c-fos expression, had stem cell morphology. These cells, however, continuously generated morphologically altered and differentiated cells upon subculturing. (iv) In other EC cell lines, which resemble stem cells more closely than the 'partially differentiated' F9 cells, c-fos expression showed either a less pronounced (P19 cells) or no differentiation-promoting effect at all (PC13 cells). Our results suggest that the c-fos gene product acts in concert with other, probably 'spontaneously' occurring events to promote differentiation of certain EC cell lines.     

Selective adhesion of embryonal carcinoma cells and differentiated cells by Ca2+-dependent sites

The specificity of adhesion between embryonal carcinoma cells and fibroblastic cells of various origins was studied. Embryonal carcinoma cells have intercellular adhesion sites requiring Ca²⁺ (CDS). These sites were found to be sensitive to proteases but resistant to them in the presence of Ca²⁺. CDS with a similar protease sensitivity is present in fibroblastic cells. When embryonal carcinoma cells of different lines were mixed, they adhered to each other nonselectively by CDS. Nonselective adhesion by CDS occurred also between fibroblastic cells of various lines. When embryonal carcinoma and fibroblastic cells were mixed, they preferentially adhered to homotypic cells. Fab fragments of antibodies raised against F9 cells (a nullipotent line of embryonal carcinoma) inhibited the adhesion between embryonal carcinoma cells but not between fibroblastic cells. This inhibitory activity of Fab was absorbed with embryonal carcinoma cells with CDS, but not with fibroblastic cells with CDS or embryonal carcinoma cells from which CDS was experimentally removed. SDS-polyacrylamide gel electrophoresis of radioiodinated cell surface proteins showed that the presence of a 140K-dalton component correlated with the presence of CDS in embryonal carcinoma cells, while the presence of a 150K-dalton component correlated with the presence of CDS in fibroblastic cells. These results suggest that CDS in embryonal carcinoma and fibroblastic cells comprise distinct molecules.     

The small heat shock protein hsp25 is accumulated in P19 embryonal carcinoma cells and embryonic stem cells of line BLC6 during differentiation

Murine embryonal carcinoma and embryonic stem cell lines were investigated with regard to the occurrence of the small heat shock protein hsp25 during cell growth and differentiation. In the embryonal carcinoma cell line F9 considerable constitutive levels of hsp25 were observed which could be slightly increased by treatment with retinoic acid. No hsp25 was found, however, in the embryonal carcinoma cell line PCC4. When analyzing the pluripotent embryonal carcinoma cell line P19 and the pluripotent embryonic stem cell line BLC6, both characterized by high differentiation capacity, no hsp25 was observed under cell culture conditions maintaining the undifferentiated state. Induction of differentiation caused by prolonged cell culture, retinoic acid treatment, or embryoid body formation, however, resulted in an increase of the level of hsp25. The finding that hsp25 is accumulated in a differentiation-dependent manner suggests that this protein is associated with processes involved in differentiation. Therefore, hsp25 can be regarded as a marker of differentiation in the investigated embryonal carcinoma cell line P19 and the embryonic stem cell line BLC6.     

Neoplastic differentiation: characteristics of cell lines derived from a murine teratocarcinoma

Monolayer cultures of a mouse teratocarcinoma were established in vitro. These cultures contained embryonal carcinoma, the malignant stem cell, and its differentiated progeny: parietal yolk sac, neuroepithelial, and mesenchymal cells. Tissues such as squamous epithelium, cartilage, striated muscle, neuroepithelium, and glands were produced from embryonal carcinoma that was maintained under conditions of long term culture. Frequent subcultivation with pancreatin allowed the establishment of cell lines of embryonal carcinoma which have been maintained for more than 18 months in vitro and continue to produce differentiated cells under specific culture conditions. Chromosomally these lines of embryonal carcinoma have a stem line of 39 chromosomes. Two lines of parietal yolk sac cells have been established which produce basement membrane, are not tumorigenic, and chromosomally are hypotetraploid. This system may yield information concerning neoplastic differentiation and its possible use in therapy for cancer.     

Altered hormonal responses: markers for embryonal and embryonic carcinoma stem cells and their differentiated derivatives

Teratocarcinoma cells in culture offer an in vitro system for studying certain aspects of embryonic differentiation. To gain some insight into regulatory systems that might be operative during early development, we have characterized the alterations that occur in the hormonal responsiveness of the membrane adenylate cyclase of different embryonal carcinoma cell lines with differentiation. Each undifferentiated embryonal carcinoma stem cell studied (F9, PCC4, PC13, P19) has an adenylate cyclase system predominantly activated by calcitonin. Of great interest is the fact that cAMP production is also enhanced specifically by calcitonin in an embryo-derived stem cell line. Differentiation of the embryonal carcinoma stem cell population toward parietal endoderm results in a decrease in calcitonin activation with a concomitant appearance of sensitivity to parathyroid hormone. Differentiation toward visceral endoderm is characterized by a lack of response of the adenylate cyclase system to both calcitonin and parathyroid hormone. These results indicate that the changes noted in adenylate cyclase hormonal responsiveness might serve as useful markers during early stages of differentiation.     

The cellular basis of myosin heavy chain isoform expression during development of avian skeletal muscles

Many pluripotent embryonal carcinoma (EC) cell lines and all embryonic stem (ES) cell lines have hitherto been maintained in the undifferentiated state only by culture on feeder layers of mitomycin C-treated embryonic fibroblasts. We now demonstrate that medium conditioned by incubation with Buffalo rat liver (BRL) cells prevents the spontaneous differentiation of such cells which occurs when they are plated in the absence of feeders. This effect is not mediated via cell selection but represents a fully reversible inhibitory action ascribed to a differentiation-inhibiting activity (DIA). BRL-conditioned medium can therefore replace feeders in the propagation of homogeneous stem cell populations. Such medium also restricts differentiation in embryoid bodies formed via aggregation of EC cells and partially inhibits retinoic acid-induced differentiation. The PSA4 EC line gives rise only to extraembryonic endoderm-like cells when aggregated or exposed to retinoic acid in BRL-conditioned medium. This suggests that DIA may be lineage-specific. DIA is a dialysable, acid-stable entity of apparent molecular weight 20,000-35,000. Its actions are reproduced neither by insulin-like growth factor-II nor by transforming growth factor-beta. DIA thus appears to be a novel factor exerting a negative control over embryonic stem cell differentiation.