Interactions between diploid embryonal carcinoma cells and early embryonic cells

Two diploid embryonal carcinoma (EC) cell lines, P10 and P19, differ in their response to the embryonic environment. P10 produces mostly normal chimeras following injection into blastocysts, whereas P19 produces mostly abnormal chimeras. In this study, P10 cells were aggregated with morulae, and all resulting fetuses were chimeric with very large contributions from the EC cells. However, all embryos were abnormal. Following aggregation of P19 cells with morulae, very few embryos were recovered and they were all non-chimeric. Both P10 and P19 were capable of forming functional gap junctions with morula cells and with the ICM of the blastocyst but not with trophoblast, showing that differences in the ability to make junctional contact with the embryo cannot explain the differences between the two cell lines.     

Differential expression of heat shock proteins in Drosophila embryonic cells following metal ion exposure

Drosophila embryonic cells were exposed to a number of metal ions that have been previously reported to act as teratogens in mammalian systems, including some known to induce heat shock (stress) proteins in a variety of model systems. This study examined the effects of these ions both on differentiation of muscles and neurons and on the induction of heat shock proteins. Metals such as arsenate, cadmium, and mercury all inhibited neuron and/or muscle differentiation in Drosophila embryonic cultures, while they also induced the entire set of heat shock proteins. Two metal ions, nickel and zinc, were shown to induce only the 22- and 23-K proteins, a pattern similar to that seen in "classical" teratogens reported previously. None of the metals tested induced only the 26- and 27-K proteins. These results suggest that there exist different regulatory mechanisms responsible for the heat shock response.     

Differential expression of mouse Disabled 2 gene in retinoic acid-treated F9 embryonal carcinoma cells and early mouse embryos.

Using a differential display PCR, we identified a differentially expressed cDNA fragment which was detectable in retinoic acid (RA) treated F9 embryonal carcinoma (EC) cells but not in untreated F9 cells. A homology search of the Gene Bank indicated that the cDNA fragment is part of the mouse homolog of the Drosophila Disabled (mDab2) gene. Aggregate cultures of F9 EC cells grown in the presence of the RA differentiated into nonmalignant cells resembling the visceral endoderm of the mouse embryo. Upon induction of endodermal differentiation with 10(-7) M RA, the gene expression of mDab2 was increased gradually during the first 96 h. Neither undifferentiated F9 cells, nor the undifferentiated aggregate cells without RA expressed mDab2. Whole-mount in situ hybridization and quantitative RT-PCR also showed that the temporal expression pattern of the mDab2 gene coincides with the initiation pattern of RA synthesis that occurs during mouse embryogenesis. Also, two alternative splicing messages of mDab2 were detected in a tissue specific manner. All the data indicate that mDab2 may play an important role in RA-induced signal transduction during mouse development.     

Spontaneous high expression of heat-shock proteins in mouse embryonal carcinoma cells and ectoderm from day 8 mouse embryo

When submitted to a heat-shock, mouse embryonal carcinoma (EC) and fibroblast cells show very different behavior. All the EC cells so far analyzed express very high levels of several heat-shock proteins (HSP) in the absence of stress and independent of their origin and culture conditions. In such cells, the 89-kd, 70-kd and 59-kd HSP are the most prominent proteins after actin. In addition, the 89-kd and 59-kd HSP are not stimulated by an arsenite shock in contrast to what is observed with fibroblasts or cells of the parietal yolk sac type. Arsenite induces the synthesis of a 105-kd polypeptide in fibroblasts but not in EC cells. In vitro differentiation of F9 cells induced by retinoic acid and dibutyryl cAMP is accompanied by a decrease in the spontaneous relative abundance of HSP and restores the arsenite-induced synthesis of the 105-kd polypeptide. EC cells are usually believed to be similar to inner cell mass cells of mouse blastocyst. Furthermore, data in the literature together with our own results suggest that the same three HSP are also spontaneously expressed in high amounts in the early mouse embryo.     

Expression of heat shock proteins by isolated mouse spermatogenic cells.

Proteins of the hsp70 family are abundant in mouse spermatogenic cells. These cells also synthesize relatively large amounts of a 70,000-molecular-weight protein (P70) that appears to be a cell-specific isoform of hsp70, the major heat-inducible protein (R.L. Allen, D.A. O'Brien, and E.M. Eddy, Mol. Cell. Biol. 8:828-832, 1988). In this study, proteins of unstressed and heat-stressed spermatogenic cells consisting of purified preparations of preleptotene, leptotene-zygotene, pachytene spermatocytes, and round spermatids were analyzed by two-dimensional polyacrylamide gel electrophoresis. Unstressed preleptotene and leptotene-zygotene spermatocytes contained little P70, whereas relatively large amounts of P70 were present in pachytene spermatocytes and round spermatids. Labeling studies showed that P70 was synthesized primarily in pachytene spermatocytes and that little synthesis occurred in round spermatids or in preleptotene and leptotene-zygotene stages of spermatogenesis. Synthesis of hsp70 was not detectable in unstressed cells but was induced in all stages of isolated germ cells following heat stress. These results indicate that P70 is expressed in a stage-specific manner during cell differentiation, whereas hsp70 is synthesized in response to stress in all populations of isolated spermatogenic cells examined.     

Differential expression of heat shock proteins in Drosophila embryonic cells following metal ion exposure

Drosophila embryonic cells were exposed to a number of metal ions that have been previously reported to act as teratogens in mammalian systems, including some known to induce heat shock (stress) proteins in a variety of model systems. This study examined the effects of these ions both on differentiation of muscles and neurons and on the induction of heat shock proteins. Metals such as arsenate, cadmium, and mercury all inhibited neuron and/or muscle differentiation in Drosophila embryonic cultures, while they also induced the entire set of heat shock proteins. Two metal ions, nickel and zinc, were shown to induce only the 22-and 23-K proteins, a pattern similar to that seen in “classical” teratogens reported previously. None of the metals tested induced only the 26-and 27-K proteins. These results suggest that there exist different regulatory mechanisms responsible for the heat shock response.     

Changes in cell surface proteins during differentiation of mouse embryonal carcinoma cells

The cell surface proteins of teratocarcinoma-derived embryonal carcinoma cells (ECC), of parietal endoderm (Pys-2 and F9-AC cl 9), and of fibroblasts (OTT6050f) were radioiodinated by a lactoperoxidase method and analyzed by two-dimensional gel electrophoresis. The combined electrophoretic profiles of proteins from a number of ECC lines allowed the determination of eight ECC-unique polypeptides. Parietal endoderm and fibroblast expressed their own unique polypeptides. The two parietal endoderm-specific polypeptides are identical to the subunits of laminin. Retinoic acid-induced differentiation of one ECC line (F9) resulted in the disappearance of polypeptides specific for ECC and the appearance of those specific for the parietal endoderm.     

Potential role of heat shock proteins in neural differentiation of murine embryonal carcinoma stem cells (P19)

HSPs (heat shock proteins) have been recognized to maintain cellular homoeostasis during changes in microenvironment. The present study aimed to investigate the HSPs expression pattern in hierarchical neural differentiation stages from mouse embryonal carcinoma stem cells (P19) and its role in heat stressed exposed cells. For induction of HSPs, cells were heated at 42°C for 30 min and recovered at 37°C in different time points. For neural differentiation, EBs (embryoid bodies) were formed by plating P19 cells in bacterial dishes in the presence of 1 mM RA (retinoic acid) and 5% FBS (fetal bovine serum). Then, on the sixth day, EBs were trypsinized and plated in differentiation medium containing neurobasal medium, B27, N2 and 5% FBS and for an extra 4 days. The expression of HSPs and neural cell markers were evaluated by Western blot, flow cytometry and immunocytochemistry in different stages. Our results indicate that HSC (heat shock constant)70 and HSP60 expressions decreased following RA treatment, EB formation and in mature neural cells derived from heat-stressed single cells and not heat-treated EBs. While the level of HSP90 increased six times following maturation process, HSP25 was expressed constantly during neural differentiation; however, its level was enhanced with heat stress. Accordingly, heat shock 12 h before the initiation of differentiation did not affect the expression of neuroectodermal and neural markers, nestin and β-tubulin III, respectively. However, both markers increased when heat shock was induced after treatment and when EBs were formed. In conclusion, our results raise the possibility that HSPs could regulate cell differentiation and proliferation under both physiological and pathological conditions.     

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.     

Differential expression of the mouse and human Thy-1 gene in embryonal carcinoma cells.

Mouse P19 embryonal carcinoma (EC) cells express on their surfaces a Thy-1 glycoprotein. The expression of Thy-1 at the mRNA and protein levels is down-regulated during differentiation induced by retinoic acid (RA). Thy-1 is also expressed in human NTERA-2 EC cells, but its expression is not down-regulated during RA-induced differentiation. As a first step towards understanding differential regulation of the mouse and human Thy-1 gene in EC cells, we have introduced genomic DNA fragments encompassing the mouse or human Thy-1 gene into NTERA-2 and P19-derived cells and analyzed surface properties of the transfectants. In the transient transfection assay, both mouse and human Thy-1 genes were expressed on cell surfaces at comparable levels. P19-derived stable transfectants exhibited great clonal variations in the expressions of the transfected Thy-1 gene products, which in part reflected copy numbers. There was no simple correlation between the expression of the transfected Thy-1 gene and two stem cell surface markers, TEC-1 and TEC-4. In the course of differentiation induced by RA several clones with a surface phenotype of EC cells exhibited a significant decrease in the expression of the transfected mouse Thy-1, whereas expression of the human Thy-1 was less efficiently down-regulated. The results suggest the presence of multiple cis- and trans-acting elements controlling expression of the mouse and human Thy-1 genes in P19 EC cells and their differentiated derivatives.