pp60src tyrosine kinase modulates P19 embryonal carcinoma cell fate by inhibiting neuronal but not epithelial differentiation

P19 embryonal carcinoma cells provide an in vitro model system to analyze the events involved in neural differentiation. These multipotential stem cells can be induced by retinoic acid (RA) to differentiate into neural cells. We have investigated the ability of several variant forms of the protein-tyrosine kinase (PTK) pp60src to modulate cell fate determination in this system. Normally, P19 cells are induced to differentiate along a neural lineage when allowed to form extensive cell-cell contacts in large multicellular aggregates during exposure to RA. Through analysis of markers of epithelial (keratin and desmosomal proteins) and neuronal (neurofilament) cells we have found that RA-induced P19 cells transiently express epithelial markers before neuronal differentiation. Under these inductive conditions, expression of pp60v-src or expression of the neuronal variant pp60c-src+ inhibited neuronal differentiation, and resulted in maintained expression of an epithelial phenotype. Morphological analysis showed that expression of pp60src PTKs results in decreased cell-cell adhesion during the critical cell aggregation stage of the neural differentiation procedure. The effects of pp60v-src on cell fate and cell-cell adhesion could be mimicked by direct modulation of Ca+(+)-dependent cell-cell contact during RA induction of normal P19 cells. We conclude that the neural lineage of P19 cells includes an early epithelial intermediate and suggest that tyrosine phosphorylation can modulate cell fate determination during an early cell-cell adhesion-dependent event in neurogenesis.     

Induced muscle differentiation in an embryonal carcinoma cell line.

Cells of the teratocarcinoma-derived line P19S1801A1 (01A1) are pluripotent embryonal carcinoma cells and can be induced to differentiate when aggregated and exposed to dimethyl sulfoxide. Many nonneural cell types appear in dimethyl sulfoxide-treated cultures, cardiac and skeletal muscle being the most easily identified. We have used immunofluorescence procedures with monoclonal antibodies directed against muscle myosin to confirm and quantitate the number of muscle cells formed. A monoclonal antibody reactive with an embryonal carcinoma-specific surface antigen was used to confirm the disappearance of undifferentiated cells after dimethyl sulfoxide treatment. Cardiac muscle cells developed within 4 to 5 days of drug exposure, but skeletal muscle cells did not become evident until 7 to 8 days. We have isolated a mutant cell line (D3) which appears to be incapable of muscle development but which does form neurons and glial cells when exposed to high retinoic acid concentrations. We propose that this system will be useful for investigation of the means by which pluripotent cells become committed to development along the striated muscle lineages.     

Transglutaminase activity and embryonal carcinoma cell differentiation

Murine embryonal carcinoma (EC) cells induced to differentiate by retinoic acid (RA) modulate transglutaminase (TGase) activity shortly after exposure to the inducer. Compounds that inhibit TGase enzyme activity in vitro can successfully block RA induced EC cell differentiation in culture. These observations suggest that TGase may play a role in mediating RA induced EC cell differentiation.     

Commitment to differentiation induced by retinoic acid in P19 embryonal carcinoma cells is cell cycle dependent

The rate at which P19 embryonal carcinoma cells in monolayer culture become anchorage dependent during differentiation induced by retinoic acid (RA) was investigated. In both nonsynchronized cultures and cultures synchronized by mitotic selection, the ability to grow in semisolid medium, characteristic of the malignant stem cell, decreased after a lag period of about 12 hr in the continuous presence of RA, prior to an increase in cell generation time. However, striking differences between synchronized and nonsynchronized cultures were observed in their commitment to differentiation following RA removal. After only 2 hr of exposure to RA, synchronized cells continued a program of differentiation in which they became anchorage dependent, while at least 24 hr of exposure was required for exponentially growing cells to become similarly committed. Induction of anchorage dependence by RA was also strikingly cell cycle dependent; 2 or 4 hr of exposure of synchronized cells to RA in G1 phase, when the intrinsic capacity for soft agar growth is low, was sufficient to commit cells to anchorage dependence, but a similar exposure in S phase was not. Together, these results suggested that interactions between cells in different cell cycle phases in asynchronous cultures influenced commitment since exposure to RA for more than one cycle (13 hr) was required for all cells to become anchorage dependent. Increased plasminogen activator secretion and epidermal growth factor binding, markers of certain differentiated cell types, increased only 3 and 5 days after RA addition, respectively, and were not induced by pulsed exposure to RA of less than 24 hr, even in synchronized cells.     

Effects of differentiation of embryonal carcinoma cells (P19) on mitochondrial DNA content in vitro

Summary The embryonal carcinoma cell line P19 is derived from mouse teratocarcinomas. These pluripotent cells can be induced to differentiate into a variety of cell types by exposure to various drugs. We used retinoic acid to induce embryonal carcinoma cells to differentiate into neuronlike cells. In this study, we show that changes occur in mitochondria during differentiation of embryonal carcinoma cells to neuronlike cells. We found that various morphologic parameters such as mitochondrial fractional area and mitochondrial size decrease as embryonal carcinoma cells differentiate into neuronlike cells. Similar changes were also observed in mitochondrial DNA content. Stereologic analysis of cell preparations provided a measure of mitochondrial fractional area per cell and mtDNA content was assessed by radiolabeled mtDNA probe. This study establishes that mitochondria are regulated as cells differentiate. This study was financially supported by the Medical Research Council of Canada.     

Retinoic acid induces embryonal carcinoma cells to differentiate into neurons and glial cells

Murine embryonal carcinoma cells can differentiate into a varied spectrum of cell types. We observed the abundant and precocious development of neuronlike cells when embryonal carcinoma cells of various pluripotent lines were aggregated and cultured in the presence of nontoxic concentrations of retinoic acid. Neuronlike cells were also formed in retinoic acid-treated cultures of the embryonal carcinoma line, P19, which does not differentiate into neurons in the absence of the drug. The neuronal nature of these cells was confirmed by their staining with antiserum directed against neurofilament protein in indirect immunofluorescence experiments. Retinoic acid-treated cultures also contained elevated acetylcholinesterase activity. Glial cells, identified by immunofluorescence analysis of their intermediate filaments, and a population of fibroblastlike cells were also present in retinoic acid-treated cultures of P19 cells. We did not observe embryonal carcinoma, muscle, or epithelial cells in these cultures. Neurons and glial cells appeared in cultures exposed to retinoic acid for as little as 48 h. We found no evidence for retinoic acid toxicity, suggesting that the effect of the drug was to induce the development of neurons and glia rather than to select against cells differentiating along other developmental pathways.     

Cell cycle analysis during retinoic acid induced differentiation of a human embryonal carcinoma-derived cell line

Several subclones of the human embryonal carcinoma (EC) cell line Tera-2 can be induced to differentiate in monolayer culture by retinoic acid (RA) to a flattened cell type with reduced growth rate. Using a method based on the transition probability model, we have analysed changes in cell cycle kinetics of Tera-2 cells during the differentiation process. Growth inhibition was shown to occur without a lag period and to be partly due to an increase in the duration of the S-phase, but with a relatively greater contribution from an increase in the duration of G1-phase. Since the fraction of the cell population in the G1-phase then doubled, cells accumulated in this part of the cycle. In contrast, the reduced proliferation rate of two murine EC cell lines, PC13 and P19, treated with RA occurs after a lag period of about two cell cycles and is mainly attributable to an increase in the duration of the S-phase. The results illustrate a differential response of human and murine EC cells to growth regulation by RA and again emphasize that although the stem cells of murine teratocarcinomas may provide a useful model, they are not identical to their human counterparts.     

Retinoic acid hydroxylase (CYP26) is a key enzyme in neuronal differentiation of embryonal carcinoma cells.

Besides nuclear retinoid receptors and cellular retinoid binding proteins also retinoic acid (RA)-synthesizing enzymes (using all-trans-retinal as substrate) and RA-catabolizing enzymes (producing hydroxylated products) may explain the specific effects of retinoids. In the past we have established an active role for 4-hydroxy-RA and 4-oxo-RA, which originally were considered to be inactive retinoids, but in fact are highly active modulators of positional specification in Xenopus development. Here we present evidence for a specific role of hydroxylated RA metabolites in the onset of neuronal differentiation. 4-Hydroxy- and 18-hydroxy-RA are products of the hydroxylation of RA by a novel cytochrome P450 (CYP)-type of enzyme, CYP26, expression of which is rapidly induced by RA. P19 embryonal carcinoma (EC) cell lines stably expressing hCYP26 undergo extensive and rapid neuronal differentiation in monolayer at already low concentrations of RA, while normally P19 cells under these conditions differentiate only in endoderm-like cells. Our results indicate that the effects on growth inhibition and RARbeta transactivation of P19 EC cells are mediated directly by RA, while the onset of neuronal differentiation and the subsequent expression of neuronal markers is mediated by hCYP26 via the conversion of RA to its hydroxylated products.     

Visceral-endoderm-like cell lines induce differentiation of murine P19 embryonal carcinoma cells

When P19 embryonal carcinoma (EC) cells were cocultured with cells from one of several established visceral-endoderm-like cell lines, the EC cells were rapidly induced to aggregate and differentiate, into cell types including mesoderm-derived cardiac and skeletal muscle. Neither parietal-endoderm- nor mesoderm-like cell lines induced aggregation or differentiation of EC cells in coculture, although a cell line with both parietal and visceral endoderm characteristics induced aggregation but not differentiation. Also, without the feeder cells aggregates of P19 failed to differentiate, provided that serum in the culture medium had been previously passed over dextran-coated charcoal to remove lipophilic substances, which may include endogenous retinoids. All experiments were carried out using serum treated in this way. Taken together, the results demonstrated that aggregation was necessary, but not sufficient, to make P19 EC cells differentiate. Direct contact between the two cell types was not necessary, since even when separated by an agar layer in cocultures, aggregates of P19 still differentiated. Medium conditioned by cells of the END-2 line, a visceral-endoderm-like derivative of P19, was particularly potent in inducing endodermal and mesodermal differentiation of single P19 aggregates, confirming the involvement of a diffusible factor secreted specifically by visceral-endoderm-like cells in this process.     

The protein composition of the nuclear matrix of murine P19 embryonal carcinoma cells is differentiation-stage dependent

The protein composition of the nuclear matrix of murine P19 embryonal carcinoma (EC) cells was compared with that of clonal derivatives of P19 EC differentiated in vitro, and with that of P19 EC cells induced to differentiate with retinoic acid (RA). Several major differences in nuclear matrix protein composition were found between the cell lines tested. Some polypeptides were found to occur only in EC cells, whereas others proved to be restricted to one or more of the differentiated derivatives. During RA treatment of EC cells a transient expression of some matrix proteins was observed. Several new proteins appeared, and others disappeared. Our data indicate that the protein composition of the nuclear matrix is a sensitive gauge for the differentiation state of cells.     

Retinoic acid resistance of the variant embryonal carcinoma cell line RAC65 is caused by expression of a truncated RARα

P19 embryonal carcinoma (EC) cells differentiate when treated with retinoic acid (RA). The P19 EC-derived mutant cell line RAC65 is resistant to the differentiation-inducing activity of RA. We show that these cells express a truncated retinoic acid receptor alpha(mRAR alpha-RAC65), probably due to the integration of a transposon-like element in the RAR alpha gene. This receptor lacks 71 C-terminal amino acids and terminates in the ligand-binding domain. In CAT assays in RAC65 cells, mRAR alpha-RAC65 fails to trans-activate the RAR beta promoter, which contains a RA-response element. In wild-type P19 EC cells mRAR alpha-RAC65 functions as a dominant-negative repressor of RA-induced RAR beta activation. Gel retardation assays demonstrate that mRAR alpha-RAC65 is still able to bind to the RA-response element of the RAR beta promoter, indicating that competition with functional RARs for the same binding site leads to the observed dominant-negative effect. In addition, in two RAC65 clones in which wild-type hRAR alpha was stably transfected RA-sensitivity was restored and in one RAR beta expression could be induced by RA. Taken together, these data show that the primary cause of RA-resistance of RAC65 cells is the expression of a defective RAR alpha, which prevents the trans-activation of RA-responsive genes and results in a loss of the ability to differentiate.     

Alterations in the developmental potential of embryonal carcinoma cells in mixed aggregates of nullipotent and pluripotent cells.

Pluripotent embryonal carcinoma cells can be triggered to differentiate in vitro by allowing them to form multicellular aggregates. Nullipotent embryonal carcinoma cells form aggregates, but further development is blocked. Pluripotent and nullipotent embryonal carcinoma cell lines were co-cultured to form mixed aggregates in order to determine whether a developmental signal produced by the pluripotent cell could induce the nullipotent cells to differentiate. Unlike pure pluripotent cell aggregates, aggregates from cultures initiated with a 1:1 mixture of pluripotent (PSA-1) and nullipotent (F9) cells formed endoderm but failed to differentiate further. The nullipotent cells did not produce a detectable soluble inhibitor of differentiation. A hypoxanthine phosphoribosyltransferase-deficient subclone of the nullipotent cell line was used so that the fate of both nullipotent and pluripotent cells could be followed in autoradiographs of histological sections of aggregates labeled with ³H-hypoxanthine. Seven day old aggregates of pure pluripotent cell cultures contained endoderm, ectoderm and embryonal carcinoma cells. On the other hand, in 7 day old mixed cell aggregates, almost all the pluripotent cells became endoderm located on the outer surface of the aggregate. The nullipotent cells in the mixed aggregates assumed an internal position and remained embryonal carcinoma cells. Following the efficiency of plating of pluripotential cells in pure and mixed aggregates as a function of time showed that viable pluripotent embryonal carcinoma cells were lost at a 10 fold greater rate in mixed cell aggregates than in pure pluripotent cell aggregates. We conclude that nullipotent embryonal carcinoma cells in mixed aggregates with pluripotent cells exert a limitation on the ability of these pluripotent cells to differentiate.     

Commitment in a murine embryonal carcinoma cell line during differentiation induced by retinoic acid

Murine embryonal carcinoma (EC) cells are induced to differentiate when cultured in the presence of retinoic acid (RA). Whereas the EC cells have a high plating efficiency, the differentiated cells have little or no colony-forming ability under the same conditions. We have assumed that the loss of colony-forming ability following exposure of EC cells to RA corresponds to the irreversible commitment of EC cells to differentiate. We found that uncommitted EC cells persist in RA-treated aggregates of EC cells and that the proportion of EC cells stabilizes at a level inversely related to the RA concentration. Both experimental evidence and mathematical modelling results are consistent with the interpretation that there is a dynamic equilibrium achieved by a balance between the processes of EC cell proliferation and differentiation. Since different cell types are induced by different RA concentrations, our results suggest that the commitment to differentiate is not related in any simple way to the developmental program which ensues.     

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.     

Up-regulation of embryonic NCAM in an EC cell line by retinoic acid

The impact of retinoic acid (RA) on the expression of the neural cell adhesion molecules (NCAMs) and their developmentally regulated polysialic acid (PSA) moiety was studied in embryonal carcinoma (EC) cell lines. These cell lines are known to be capable of RA-induced differentiation into neurons (murine P19 cells) or parietal endoderm (murine F9 cells), respectively. Monoclonal antibodies were employed to monitor expression of NCAM and PSA. F9 and P19 cells were both found to express NCAM but only P19 cells carried the highly polysialylated "embryonic form" of NCAM (E-NCAM). The amount of NCAM in aggregated P19 cells but not in F9 cells was dramatically increased upon treatment with RA. Since NCAMs play an important role in cell interactions during embryogenesis it is tempting to speculate that the regulative impact of RA on NCAMs is related to its morphogenic property.     

Induction of c-fos and AFP expression in a differentiating teratocarcinoma cell line

The introduction of a c-fos expression vector has been shown to potentiate spontaneous differentiation in teratocarcinoma cells. We have studied a teratocarcinoma stem cell line which can be induced to differentiate with dimethylsulfoxide (DMSO) to determine endogenous c-fos expression during the process of differentiation. c-Fos expression increases dramatically as P19S1801A1 embryonal carcinoma cells are induced to differentiate into a variety of cell types. Expression peaks 12 days after the start of aggregate culture about the same time as alphafetoprotein (AFP), a characteristic of visceral endoderm differentiation, as demonstrated by RNA hybridization to specific probes, ELISA, and immunofluorescent staining with specific antibodies. However, most differentiated cells expressed c-fos, while AFP was expressed in a minor fraction (less than 5%). The data suggest that c-fos is correlated with differentiation of teratocarcinoma cells but not specifically to visceral endoderm formation.     

Inducer-dependent phenotypic divergence in an embryonal-carcinoma cell line

Abstract. In monolayer cultures, embryonal carcinoma (EC) cells from the cell line Nulli-SCCI can be induced to differentiate at high efficiency by exposure to either retinoic acid or hexamethylenebisacetamide. Depending on which inducing agent is used, two distinct differentiated phenotypes result. These phenotypes resemble two of the earliest differentiated derivatives of the cells of the inner cell mass of a mouse blastocyst, i.e., parietal and visceral endoderm. Both differ from EC cells as well as from each other on the basis of their morphology, antigenic expression, secretion of plasminogen activator, and protein-synthetic profiles.