Semisyngeneic hybrid resistance to murine teratocarcinoma cells

Resistance to two cultured lines of murine embryonal carcinoma was studied in F1 hybrids constructed between the tumor-syngeneic mouse strain 129/J and several allogeneic strains. Three of four such hybrid strains were significantly more resistant to the multipotent embryonal carcinoma line PCC3 than the tumor-syngeneic 129/J parent strain. All hybrid strains tested showed significantly higher resistance to the nullipotent embryonal carcinoma line F9 than the syngeneic strain. Hybrid resistance to embryonal carcinoma lines does not require a hybrid H-2 complex. Several kinds of evidence indicate that this hybrid resistance has an immunological basis.     

Semisyngeneic hybrid resistance to murine teratocarcinoma cells

Resistance to two cultured lines of murine embryonal carcinoma was studied in F₁ hybrids constructed between the tumor-syngeneic mouse strain 129/J and several allogeneic strains. Three of four such hybrid strains were significantly more resistant to the multipotent embryonal carcinoma line PCC3 than the tumor-syngeneic 129/J parent strain. All hybrid strains tested showed significantly higher resistance to the nullipotent embryonal carcinoma line F9 than the syngeneic strain.Hybrid resistance to embryonal carcinoma lines does not require a hybridH-2 complex.Several kinds of evidence indicate that this hybrid resistance has an immunological basis.     

The response of several murine embryonal carcinoma cell lines to stimulation of differentiation by alpha-difluoromethylornithine

In an attempt to better establish the relationship between polyamine levels and the differentiation of embryonal carcinoma cells, we have examined the ability of alpha-difluoromethylornithine (DFMO), a known inducer of differentiation in one embryonal carcinoma cell line, to stimulate the differentiation of embryonal carcinoma cells from a variety of cell lines. Differentiation was monitored using a variety of criteria including morphological alterations and changes in biochemical and antigenic parameters. Depending on their response to difluoromethylornithine, three classes of cell lines could be identified, those which 1) differentiate extensively, 2) differentiate poorly, and 3) fail to differentiate. Three different classes of embryonal carcinoma cell lines reflect differential changes in polyamine levels resulting from inhibition of ornithine decarboxylase enzyme activity by DFMO. The specific cell lines which exhibit large decreases in both ornithine decarboxylase activity and polyamine levels also show extensive differentiation. The cell lines which show only moderate decreases in enzyme activity and polyamines differentiate poorly while the cell lines which fail to respond to DFMO in that polyamines do not drop below the threshold level necessary to induce differentiation fail to differentiate. These studies suggest that decreases in intracellular polyamines induce EC cell differentiation in vitro.     

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.     

Two multipotent embryonal carcinoma cell lines irreversibly differentiate in defined media

Two unrelated multipotent embryonal carcinoma cell lines, OC-15S1 and 1003, have been cultured in hormone-supplemented defined media in order to identify the signals that influence their differentiation. Previous studies have shown that F9 embryonal carcinoma cells can be grown for many generations in the defined medium, EM-3, which contains fibronectin, insulin, and transferrin in place of serum. F9 cells, which only differentiate into a few cell types, undergo little or no differentiation in EM-3 unless an inducer is present (A. Rizzino and C. Crowley, 1980, Proc. Natl. Acad. Sci. USA77, 457–461). This report demonstrates that, in contrast to F9, OC-15S1 and 1003 embryonal carcinoma cells do not proliferate in EM-3. Instead, the cells differentiate. However, the differentiated cells do not survive in EM-3 unless it is supplemented with factors such as purified serum lipoproteins. In EM-3 containing high-density lipoprotein, a population of differentiated cells, devoid of embryonal carcinoma cells, is formed. The differentiated cells that appear exhibit an epithelioid morphology throughout the culture. These cells also secrete plasminogen activator and two different criteria argue that it is the type released by parietal endoderm. This suggests that, under the influence of the defined medium, both multipotent embryonal carcinoma cell lines differentiate at high frequency into parietal endoderm. It was also determined that fibronectin promotes the differentiation of OC-15S1 and 1003 in serum-containing media, and this suggests that fibronectin is at least partly responsible for the differentiation observed in EM-3 plus high-density lipoprotein. In light of these findings, it is suggested that fibronectin may directly influence cellular differentiation during early mammalian development.     

Functional cloning of mouse chromosomal loci specifically active in embryonal carcinoma stem cells.

Chromosomal loci that are specifically active in embryonal carcinoma stem cells were cloned from the mouse genome by functional selection. P19 cells, a pluripotent embryonal carcinoma cell line, were transfected with an enhancer trap (a plasmid containing an enhancerless inactive neo gene), and NEO+ transformants were isolated. All of the NEO+ cell lines retained pluripotency and expressed the neo gene. When the cells were induced to differentiate, most of the cell lines continued to express the neo gene, while the neo gene in some cell lines became repressed. From the latter group of cell lines, we have cloned the integrated neo gene plus the flanking cellular DNA sequences. Three of the six cloned DNAs possessed a high NEO+-transforming activity in undifferentiated P19 cells. Among these three, two (015 and 052) were inactive in differentiated P19 cells and NIH 3T3 cells, while the remaining one was active in these differentiated cells. Deletion analysis suggested that both 015 and 052 contain two regulatory elements (promoter and enhancer) of cellular DNA origin. The putative enhancer and promoter are separated by at least 6 kilobases in 015 and 1 kilobase in 052. Therefore, 015 and 052 cloned fragments contain regulatory DNA elements that are specifically active in the embryonal carcinoma stem cells.     

Isolation and characterization of a near-diploid differentiated cell line from a murine teratocarcinoma that differentiates into muscle

Cell lines corresponding to various cell lineages of the mouse embryo have been isolated from murine teratocarcinomas. Embryonal carcinoma cell lines are developmentally equivalent to the embryonic ectoderm or inner cell mass. Most of these cell lines have a modal chromosome number equal or close to 40, the normal mouse complement. However, cell lines corresponding to more advanced cell lineages (e.g., endoderm) are tetraploid or hypotetraploid and display multiple chromosomal rearrangements. This paper describes the isolation of a near-diploid differentiated cell line (LT-D) from an LT teratocarcinoma. The modal chromosome number of LT-D is 40, and this number is stable during at least 12 mo of continuous culture. LT-D cells are morphologically distinct from embryonal carcinoma cells and no longer express the SSEA-1 cell surface antigen or high alkaline phosphatase activity characteristic of embryonal carcinoma cells. LT-D cells can be induced to fuse into structures resembling myotubes. The formation of these structures is accompanied by expression of the muscle-specific isozyme of creatine phosphokinase and desmin, a muscle-specific component of intermediate filaments. Lastly, LT-D cells do not form tumors in syngenetic mice.     

Transforming growth factor-β and its receptor are differentially regulated in human embryonal carcinoma cells

The human embryonal carcinoma cell lines Tera-2 clone 13 and NTera-2 clone D1 can be induced by retinoic acid to differentiate in vitro into neuroectodermal derivatives. The undifferentiated cells are rapidly proliferating and tumorigenic, whereas retinoic-acid-treated cells possess a decreased growth rate, lose their transformed phenotype and show a finite lifespan. Differentiation is accompanied by a marked increase in the levels of mRNA for TGF-beta 1 and TGF-beta 2 and the production of TGF-beta activity. Just like murine embryonal carcinoma cells the growth of Tera-2 clone 13 cells is not affected by the addition of either TGF-beta 1 or TGF-beta 2 to the culture medium. In contrast to published data on murine embryonal carcinoma cells, Tera-2 clone 13 and NTera-2 clone D1 cells bind TGF-beta 1 with high affinity, which is due to the presence of type-III TGF-beta receptors. Furthermore, and again in contrast to murine embryonal carcinoma cells, treatment of the human embryonal carcinoma cells with retinoic acid causes a nearly complete loss of TGF-beta 1 binding sites. These results are discussed in the light of similarities and differences in the regulation of growth and differentiation of human and murine embryonal carcinoma cell lines.     

Isolation and characterization of a near-diploid differentiated cell line from a murine teratocarcinoma that differentiates into muscle

Summary Cell lines corresponding to various cell lineages of the mouse embryo have been isolated from murine teratocarcinomas. Embryonal carcinoma cell lines are developmentally equivalent to the embryonic ectoderm or inner cell mass. Most of these cell lines have a modal chromosome number equal or close to 40, the normal mouse complement. However, cell lines corresponding to more advanced cell lineages (e. g., endoderm) are tetraploid or hypotetraploid and display multiple chromosomal rearrangements. This paper describes the isolation of a near-diploid differentiated cell line (LT-D) from an LT teratocarcinoma. The modal chromosome number of LT-D is 40, and this number is stable during at least 12 mo of continuous culture. LT-D cells are morphologically distinct from embryonal carcinoma cells and no longer express the SSEA-1 cell surface antigen or high alkaline phosphatase activity characteristic of embryonal carcinoma cells. LT-D cells can be induced to fuse into structures resembling myotubes. The formation of these structures is accompanied by expression of the muscle-specific isozyme of creatine phosphokinase and desmin, a muscle-specific component of intermediate filaments. Lastly, LT-D cells do not form tumors in syngenetic mice. This work was supported in part by National Institutes of Health, Bethesda, MD, Grant CA-15823 and by a departmental gift from R. J. Reynolds Industries, Inc.     

A Reproducible Colonial Morphology Formed by Individual Pluripotent Embryonal Carcinoma Cells in Culture and Selection of Variants

Embryonal carcinoma cells are stem cells equivalent to those of the early embryo which can be grown in vitro and which under certain conditions can differentiate into many cell types. Events in this differentiation process are numerous and complex, thus a system for the analysis of clonal differentiation is essential. In this paper I report that individual pluripotent embryonal carcinoma cells can each give rise to colonies, in the absence of a feeder layer but in the presence of β-mercaptoethanol, that show a distinctive and reproducible gross morphology. Embryonal carcinoma cell lines can be derived from the stem cells in these colonies. Furthermore, variant cell lines can be derived from those colonies showing an altered gross morphology. These lines when cloned as above give rise to colonies showing a gross colonial morphology different to that of wild-type. These variant lines have been shown to be embryonal carcinoma cell lines. These findings indicate that genetic and cell lineage analysis of embryonal carcinoma cell differentiation might be possible.     

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.     

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.     

Derivation of a nondifferentiating clone from multipotential PSA1 embryonal carcinoma cells

The ability of PSA1 embryonal carcinoma cells to differentiate when grown as clones on a monolayer of feeder cells was assessed using morphological criteria. The first appearance of a differentiated phenotype within a clone occurred at different times for individual clones after 10 days of culture, this being apparently unrelated to clone size or cell density. Those clones which showed no morphological evidence of differentiation after several weeks (about 5% of the clones observed) were selected and recloned with the aim of finding variant lines which were stably deficient in their differentiating ability. Undifferentiated clones - identified and selected after about 3 weeks of growth - were of three different types after recloning: those similar to control cultures of PSA1, those having delayed and reduced differentiation frequency, and those having variable frequencies of differentiation in replicate reclonings. The isolation of a variant with a more complete differentiation deficiency was accomplished by selecting ten nondifferentiating clones growing isolated in individual culture wells after 5 weeks of culture. One of these, T2H9, proved to be a stable, differentiation-deficient variant subline with less than 3% of its clones showing any morphological evidence of differentiation in five repeated reclonings. It was also determined that the frequency of undifferentiated clones in embryonal carcinoma cultures increased from 0.3% to 54% after 11 months of in vitro aging, i.e., approximately 200 cell doublings. The isolation of clonal embryonal carcinoma cell derivatives which are stable, heritable differentiation variants provides resources for somatic-cell genetic analysis of stem-cell pluripotency.     

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.     

Synthesis and retention of fibronectin (LETS protein) by mouse teratocarcinoma cells.

Mouse teratocarcinoma cells in culture were examined for both the synthesis (by metabolic labelling) and surface accumulation (by indirect immunofluorescence) of fibronectin, a glycoprotein with subunits of molecular weight 220000 D known to form part of the extracellular matrix of many cells in vivo. Although lines of both pluripotent and nullipotent embryonal carcinoma cells synthesize the protein and release it into the medium, they do not retain it on their surfaces. Monolayers of the endoderm line PSA5-E both synthesize fibronectin and lay it down in an extracellular network. A line of PYS parietal endoderm cells does not retain surface fibronectin, although it does accumulate other extracellular matrix material. When pluripotent embryonal carcinoma cells differentiate into cystic embryoid bodies, fibronectin accumulates in a basement membrane below the outer endoderm cells (both visceral and parietal-like) and may play a transient role in organizing the inside cells into an epithelial layer.     

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.     

Retinoic acid fails to induce differentiation in human teratocarcinoma cell lines that express high levels of a cellular receptor protein

Human embryonal carcinoma (EC) cells and other human teratocarcinoma-derived cells lines were not observed to differentiate in culture in response to retinoic acid. Nevertheless, they express high levels of a cellular binding protein (cRABP) which, in murine EC cells, appears to be necessary for the induction of differentiation by retinoic acid.     

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.     

Smooth muscle actin expression during P19 embryonal carcinoma differentiation in cell culture

P19 embryonal carcinoma (EC) cells can be induced in vitro to differentiate into cells resembling those normally formed in the embryo. Among these cell types is one whose morphology is fibroblast-like. Using indirect immunofluorescence and Western blot analysis with antibodies directed against various isoforms of actin, many of these fibroblast-like cells were found to express smooth muscle actin isoforms. Northern blot analysis of RNA indicated the presence of a smooth muscle-specific isoform of myosin heavy-chain mRNA in immortal lines of these fibroblast-like cells. These results suggest that these fibroblast-like cells resemble fetal myofibroblastic or myoepithelial cells, which have a wide distribution during embryonic development.     

DNA methylation,retroviruses, and embryogenesis

By exposing preimplantation embryos to Moloney leukemia virus (M-MuLV), we have previously derived substrains of mice designated as Mov-1-Mov-13 which genetically transmit the virus from one generation to the next. In some of the substrains the inserted viral genome becomes activated at specific stages of embryogenesis and the available evidence suggests that these viral genomes are developmentally regulated. To investigate the effect of cellular differentiation on virus expression, M-MuLV was introduced either into preimplantation or postimplantation mouse embryos or into embryonal carcinoma (EC) cells. Whereas preimplantation embryos or EC cells are not permissive for virus expression, efficient replication occurred in postimplantation embryos or in differentiated cell lines. The viral genomes introduced into early embryonal cells were highly methylated and noninfcctious when analyzed in the adult. In contrast, viral genomes introduced into postimplantation embryos or into differentiated cells remained unmethylated and were infectious in a transfection assay. These results demonstrate an efficient de novo methylation activity which appears to be involved in repression of genes introduced into pluripotent embryonal cells and which is not observed in cells of the postimplantation embryo or in differentiated cells in tissue culture.