Protein kinase C and phorbol ester receptor expression related to growth and differentiation of nullipotent and pluripotent embryonal carcinoma cells

We have characterized effects of phorbol, 12-myristate 13 acetate (PMA) on growth and differentiation in a nullipotent embryonal carcinoma (EC) cell line, F9, in a pluripotent EC line, P19, and in the differentiated derivatives of these cells, In P19EC and F9EC PMA addition resulted in inhibition of growth, while in the differentiated derivates PMA was mitogenic. PMA did not induce differentiation in EC cells but potentiated the retinoic acid (RA) induced differentiation in P19EC, although, not in F9EC. Rapid morphological changes by PMA were seen in P19EC and two differentiated derivatives which represent different stages of differentiation. In F9 no rapid morphological changes were induced by PMA. Using [3H]phorbol dibutyrate as a ligand we showed that during differentiation into endoderm-like cells the number of phorbol ester receptors increases, while in epithelial-like derivatives no increase is found. In differentiated cells with an increased number of phorbol ester receptors, the cytoplasmic Ca2+- and phospholipid-dependent protein kinase (the putative receptor for phorbol esters) activity was also increased. Only in those derivatives where the number of phorbol ester receptors is increased, is the binding of epidermal growth factor (EGF) inhibited by PMA. These results suggest a relationship between levels of expression of phorbol ester receptors, cytoplasmic protein kinase C and biological effects, namely rapid morphological changes, altered growth, potentiation of RA induced differentiation, and inhibition of EGF binding.     

Metabolic cooperation in aggregates of embryonal carcinoma cells

Metabolic cooperation may be associated with the processes of compaction and subsequent differentiation in aggregates of embryonal carcinoma cells (ECC). To determine if the gap junctions present in loose and compacted aggregates of H6 ECC are active in metabolic cooperation, aggregates of each type containing a mixture of 5-bromodeoxyuridine- and 6-thioguanine-resistant H6 cells were exposed to HAT medium, 6-thioguanine, or [³H]thymidine. These three methods indicated that some crossfeeding occurred through the small clusters of gap junctions in loose aggregates and more crossfeeding occurred through the larger clusters of gap junctions in compacted aggregates.     

Epithelial layer formation in differentiating aggregates of F9 embryonal carcinoma cells

F9 embryonal carcinoma (EC) cells, cultured in suspension in medium containing 5 X 10(-8) M retinoic acid, aggregate and differentiate into embryoid bodies with an outer layer of visceral endoderm cells that synthesize and secrete alphafetoprotein (AFP) (Hogan, B. L. M., A. Taylor, and E. Adamson, 1981, Nature (Lond.). 291:235-237). Here we analyze the formation of the outer layer of cells as a model for epithelial differentiation. Three morphological phases are described, but analyses of cell numbers and the synthetic rates of some proteins, as well as the appearance of markers of visceral endoderm and basement membrane, show that the formation of the outer layer occurs as an orderly progression of multiple events. The markers used to follow the ontogeny of epithelial layer formation include SSEA-1, l, and i blood group antigens, laminin, fibronectin, type IV collagen, cytoskeletal intermediate filament proteins (vimentin, Endo A, and B), and AFP. The onset of epithelium formation occurs between the third and fourth day of culture, but its function is maximally expressed only when it is well organized. We found the rate of AFP secretion to be a measure of the proper alignment and maturity of the epithelium which occurs at the seventh or eighth day. This model of epithelium formation may help to explain how similar processes occur during embryogenesis.     

Spontaneous differentiation in the colonies of a nullipotent embryonal carcinoma cell line (F9)

Abstract. Experiments were undertaken to reveal the spontaneous differentiation capacity of the nullipotent F9 embryonal-carcinoma (EC) cell line in colonies derived from single cells. Culture conditions which alllowed the development of neuroblasts in colonies of the multipotent EC cell line (PCC3) were worked out, and comparative studies on neuroblast differentiation in PCC 3 and F 9 colonies were conducted. Neural-cell-specific silver impregnation, selective staining of cells having electrically excitable membranes with merocyanine 540 and the observation of nerve processes were considered as differentiation markers. The appearance of neuroblasts in F9 and PCC3 colonies could be detected from the 6th day after seeding. The development of neuroblasts was less prevalent in high-density cultures, especially in the case of F9. By the 8th day in differentiating colonies, PCC3 cells lost much of their colony-forming activity, while F9 cells preserved their original high plating efficiency, in spite of advanced differentiation. The determination of growth parameters during differentiation in colonies led to the conclusion that F9 cells had lost certain growth-control mechanisms which normally restrict the clonal growth of EC cells. It is suggested that the phenomenon of nullipotence may be analysed in terms of the coordinated regulation of proliferation and differentiation of EC cells.     

Variant embryonal carcinoma cells lacking SSEA-1 and Forsmann antigens remain developmentally pluripotent

Six embryonal carcinoma (EC) cell lines that are resistant to the cytotoxic, galactose-specific lectin abrin were isolated from mutagenized populations of either PSA-1 or F9 cells. The LD10 for each of the variant lines was at least 150-fold greater than that for parental cells. Indirect cytotoxicity tests demonstrated that all of the variant cell lines lacked both Stage Specific Embryonic Antigen-1 (SSEA-1, less than 1% of wild-type levels) and Forsmann antigen (less than 5% of wild-type levels). When abrin-resistant cells were fused to previously isolated SSEA-1-negative cells (M. J. Rosenstraus (1983), Dev. Biol. 99, 318-323) that express Forsmann antigen, the resulting hybrids expressed SSEA-1. This implies the mutation conferring abrin resistance is in a different gene than that defined by the previously isolated mutation. Thus, we have identified two genes that are required for SSEA-1 expression, one of which also appears to be required for Forsmann antigen expression. The F9-derived variants differentiated into visceral-like or parietal-like endoderm when treated with retinoic acid in the absence or presence of 8-bromo-cAMP, respectively. PSA-1-derived variants formed differentiated teratocarcinomas containing derivatives of all three germ layers. Thus the SSEA-1 and Forsmann haptenic determinants are not required for EC cells to differentiate into a broad spectrum of cell types; nor do they appear to be involved in the cell-cell interactions that are postulated to regulate visceral versus parietal endoderm differentiation.     

Spontaneous differentiation in the colonies of a nullipotent embryonal carcinoma cell line (F9)

Experiments were undertaken to reveal the spontaneous differentiation capacity of the nullipotent F9 embryonal-carcinoma (EC) cell line in colonies derived from single cells. Culture conditions which allowed the development of neuroblasts in colonies of the multipotent EC cell line (PCC3) were worked out, and comparative studies on neuroblast differentiation in PCC3 and F9 colonies were conducted. Neural-cell-specific silver impregnation, selective staining of cells having electrically excitable membranes with merocyanine 540 and the observation of nerve processes were considered as differentiation markers. The appearance of neuroblasts in F9 and PCC3 colonies could be detected from the 6th day after seeding. The development of neuroblasts was less prevalent in high-density cultures, especially in the case of F9. By the 8th day in differentiating colonies, PCC3 cells lost much of their colony-forming activity, while F9 cells preserved their original high plating efficiency, in spite of advanced differentiation. The determination of growth parameters during differentiation in colonies led to the conclusion that F9 cells had lost certain growth-control mechanisms which normally restrict the clonal growth of EC cells. It is suggested that the phenomenon of nullipotence may be analysed in terms of the coordinated regulation of proliferation and differentiation of EC cells.     

Cell-surface changes during in vitro differentiation of pluripotent embryonal carcinoma cells

When aggregates of HM-1 embryonal carcinoma (EC) cells were exposed to 10(-6) M retinoic acid for 2 days and cultured in medium lacking retinoic acid, they differentiated to nerve cells, endoderm cells, and myoblasts. Cells 2 days after initial exposure to retinoic acid were not significantly different from the parental EC cells, as judged by cell-surface architecture and by reactivity to lectins. On the fourth day, the surface of the aggregates was covered with two kinds of cells distinguishable from the parental cells. The round cells with short villi seemed to be precursors to endoderm cells. Receptors for Dolichos biflorus agglutinin (DBA) newly appeared and receptors for peanut agglutinin (PNA) were still expressed on their surfaces. The other cells, which were round cells with a few processes, might be precursors to nerve cells. PNA receptors had disappeared from their surfaces, and DBA receptors were not expressed. On the sixth day of differentiation, possible precursors to myoblasts were detected; they were flat cells with smooth surfaces. These cells lacked cell-surface receptors for the two lectins, while the precursor cells and the myoblasts excreted intercellular fibers reacting with PNA. HM-1 cells synthesized much embryoglycan, the structure of which was similar to that of the glycan isolated from quasinullipotent F9 cells. The only difference was that the glycan from HM-1 cells lacked DBA binding sites. Synthesis of fucosylated embryoglycan mainly decreased between the second and fourth day of differentiation. As above, cell-surface changes occurred mainly between the second and fourth day. The period seems to be important in determining the fate of the cells, since endoderm cells were scarcely seen among differentiated cells which had been continuously exposed to 10(-6) M retinoic acid during the period.     

Expression of c-myb in embryonal carcinoma cells and embryonal stem cells

Mouse c-myb has been implicated in the regulation of differentiation and proliferation of haematopoietic cells. Analysis of the chromatin structure of the promoter region of c-myb in embryonal carcinoma (EC) cells and embryonal stem (ES) cells reveals a DNAse I-hypersensitive site coincident with a site found in c-myb-expressing haematopoietic cells, but absent in murine fibroblasts (which do not express c-myb). EC and ES cells were found to express c-myb mRNA, albeit at a level lower than found in haematopoietic cells. Differentiation of ES cells into embryoid bodies resulted in an elevated level of c-myb expression.     

Calcium-induced compaction and its inhibition in embryonal carcinoma cell aggregates

H6 embryonal carcinoma cells form aggregates of cells in culture medium which contains 2 mM calcium. These aggregates are described as uncompacted, indicating that the individual cells of the aggregate are spherical and are in limited contact with each other. In contrast, compaction of the aggregate, induced by increasing the calcium concentration, results in a tight mass of cells flattened against one another and connected by intercellular junctions. At least 85-97% of the aggregates undergo compaction in 7 mM calcium and are subsequently decompacted if removed to 2 mM calcium. Since calcium ionophore A23187 does not induce compaction, extracellular rather than intracellular calcium seems to be the limiting factor. We have demonstrated that this calcium-induced morphogenetic change is sensitive to inhibition by agents which also prevent the calcium-dependent compaction of the 8-cell mouse embryo. The cytoskeletal-binding drugs tetracaine HCl, colcemid, vinblastine, colchicine, and cytochalasin B each inhibit compaction of H6 aggregates. Interference at surface molecule sites by exposure to the lectins wheat germ agglutinin or concanavalin A or by interruption of glycosylation with exposure to tunicamycin, or by reaction with anti-H6 Fab or anti-F9, also prevent compaction. Since the mouse embryo and embryonal carcinoma cells share certain processes which are involved in initiating and maintaining compaction, these processes and their subsequent roles in differentiation may be examined using embryonal carcinoma cell aggregates.     

Mode of cell surface marker changes during retinoic acid-induced differentiation in pluripotent embryonal carcinoma cells

Pluripotent teratocarcinoma cell line, 311, was cultured in the presence of retinoic acid (RA) and studied for the processes of early marker changes associated with cell differentiation. The cell populations that have lost peanut agglutinin (PNA), Lotus tetragonolobus agglutinin (LTA) or wheat germ agglutinin (WGA) receptor increased in proportion to the period since the start of RA treatment. The kinetics of the appearance of these receptor-negative cell populations suggests that the differentiating cells lose lectin receptors in the order of PNA, LTA and WGA. However, the changes in F9 antigen(s) and LTA receptor occurred at an equal frequency in PNA+ and PNA- cells, indicating that, although the loss of lectin receptors takes place in a distinct order, the change in each receptor itself proceeds independently of the state of other lectin receptors.     

Alterations in tumorigenicity of embryonal carcinoma cells by IGF-I triple-helix induced changes in immunogenicity and apoptosis

IGF-I antisense gene therapy has been applied successfully to animal models of glioma, hepatoma and teratocarcinoma. The antisense strategy has shown that tumor cells transfected with vectors encoding IGF-I antisense RNA lose tumorigenicity, become immunogenic and are associated with tumor specific immune response involving CD8+ lymphocytes. An IGF-I triple helix approach to gene therapy for glioma was recently described. The approach we have taken is to establish parameters of change using the IGF-I triple helix strategy. PCC-3 embryonal carcinoma cells derived from murine teratocarcinoma which express IGF-I were used as a model. The cells were transfected with vector which encodes an oligoribonucleotide that forms RNA-IGF-I DNA triple-helix structure. The triple-helix stops the production of IGF-I. Cells transfected in this manner underwent changes in phenotype and an increase in MHC-I and B-7 cell surface molecules. They also showed enhancement in the production of apoptotic cells (60-70%). The "triple helix" transfected cells lost the ability to induce tumor when injected subcutaneously in syngeneic 129 Sv mice. When co-transfected in vitro with expression vectors encoding both MHC-I and B-7 cDNA in antisense orientation, the "triple-helix" transfected cells were down-regulated in expression of MHC-I and B-7 and the number of apoptotic cells was significantly decreased. Injection of the doubly co-transfected cells into 129 Sv mice was associated with induction of teratocarcinoma. Comparison between antisense and triple-helix transfected cells strategies showed similar immunogenic and apoptotic changes. The findings suggest that triple-helix technology may offer a new clinical approach to treatement of tumors expressing IGF-I.     

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.     

Cell position regulates endodermal differentiation in embryonal carcinoma cell aggregates

It has been suggested that cell position regulates endodermal differentiation in mouse embryo inner cell masses and in aggregates of embryonal carcinoma (EC) cells. This hypothesis states that cells at the interface between the cell mass and blastocoel fluid or culture medium differentiate into endoderm, whereas internally located cells follow alternative developmental pathways. To test the cell position hypothesis, pluripotent PSA-1 cells were aggregated with hypoxanthine phosphoribosyltransferase-deficient, parietal-like, endodermal cells. The resulting aggregates consisted of cores of PSA-1 cells surrounded by endodermal cells. Autoradiography was used to distinguish between endodermal cells that were the products of EC cell differentiation and the exogenous endoderm. Alkaline phosphatase staining was used to distinguish EC cells from endodermal cells. As predicted by the cell position hypothesis, the PSA-1 EC cells, all of which were internally located, did not differentiate into endodermal cells. Nonspecific inhibition of differentiation did not account for the lack of PSA-1-derived endoderm since the PSA-1 cells in such aggregates did differentiate into columnar ectodermal-like cells. Similar experiments were also conducted with F9 cells. In this case, aggregation cultures contained retinoic acid to induce F9 cells to differentiate into visceral endoderm. In cultures containing F9 cells surrounded by parietal-like endodermal cells, no F9-derived endoderm was detected either autoradiographically or by assaying for alpha-fetoprotein production, a visceral endoderm marker. Thus, retinoic acid-induced endodermal differentiation was also regulated by cell position. Collectively, the above results provide strong evidence for the hypothesis that cell position regulates endodermal differentiation in aggregates of EC cells.     

Teratocarcinoma X friend erythroleukemia cell hybrids resemble their pluripotent embryonal carcinoma parent.

Five independent clones of somatic cell hybrids have been produced by fusing FBU Friend erythroblastic leukemia cells with cells of the pluripotent teratocarcinoma-derived embryonal carcinoma line PCC4azal. All five lines closely resemble their PCC4azal parent. They look like embryonal carcinoma cells by phase contrast and electron microscopy, have high levels of alkaline phosphatase but low levels of acetylcholinesterase, and, like PCC4azal, express both LDH-A and LDH-B. Tumors produced from hybrid lines often contain large amounts of differentiated tissue, including representatives of all three of the classical germ layers. These results suggest that the genome of a pluripotent mammalian cell, far from being unconditionally susceptible to whatever signals differentiated cells employ to maintain their stable phenotype, may itself be able to “reset” the genome of the differentiated cell.     

Neural differentiation of pluripotent mouse embryonal carcinoma cells by retinoic acid: inhibitory effect of serum

In both embryonal carcinoma (EC) and embryonic stem (ES) cells, the differentiation pathway entered after treatment with retinoic acid (RA) varies as it is based upon different conditions of culture. This study employs mouse EC cells P19 to investigate the effects of serum on RA-induced neural differentiation occurring in a simplified monolayer culture. Cell morphology and expression of lineage-specific molecular markers document that, while non-neural cell types arise after treatment with RA under serum-containing conditions, in chemically defined serum-free media RA induces massive neural differentiation in concentrations of 10(-9) M and higher. Moreover, not only neural (Mash-1) and neuroectodermal (Pax-6), but also endodermal (GATA-4, alpha-fetoprotein) genes are expressed at early stages of differentiation driven by RA under serum-free conditions. Furthermore, as determined by the luciferase reporter assay, the presence or absence of the serum does not affect the activity of the retinoic acid response element (RARE). Thus, mouse EC cells are able to produce neural cells upon exposure to RA even without culture in three-dimensional embryoid bodies (EBs). However, in contrast to standard EBs-involving protocol(s), neural differentiation in monolayer only takes place when complex signaling from serum factors is avoided. This simple and efficient strategy is proposed to serve as a basis for neurodifferentiation studies in vitro.     

Cell lines with developmental potential restricted to mesodermal lineages isolated from differentiating cultures of pluripotential P19 embryonal carcinoma cells

Embryonal carcinoma (EC) cells are developmentally pluripotential cells which can be induced to differentiate in cell culture to form a wide variety of cell types. To investigate the lineage relationships between cells of different types, we set out to isolate cell lines with multiple but restricted developmental potentials from differentiating cultures of P19 cells, a line of EC. By selecting for differentiated cells capable of anchorage-independent growth, we isolated cell lines which differentiated in high density cultures to form at least two cell types; myocytes that resembled fetal skeletal muscle cells and loose connective tissue cells that secreted large amounts of type I collagen. These results suggest that skeletal myocytes and connective tissue share a common precursor and that stem cells with limited but multiple developmental potentials can be isolated from differentiating cultures of P19 cells.