Mitsuko Kosaka

Reversible effects of sodium butyrate on the differentiation of F9 embryonal carcinoma cells

We have studied effects of sodium butyrate on embryonal carcinoma F9 cell differentiation. In the presence of sodium butyrate, F9 cells underwent rapid and drastic morphological changes and expressed marked increases in mRNA levels of various differentiation markers. When sodium butyrate was removed from the cultures, all the examined phenotypes of F9 cell differentiation rapidly reverted to the characteristics of undifferentiated stem cells. However, under the same conditions, when cycloheximide or actinomycin D was added to the cultures, such phenotypic reversion was not observed, but high mRNA levels of the differentiation markers as well as altered cell morphology were retained. These results indicated that the effects of sodium butyrate on induction of teratocarcinoma cell differentiation were reversible and that de novo syntheses of some mRNA(s) and protein(s) were necessary for the reversion of differentiated cells to stem cells.

Expression of c-kit protooncogene is stimulated by cAMP in differentiated F9 mouse teratocarcinoma cells☆

Protooncogene c-kit, a transmembrane tyrosine kinase receptor, was recently shown to map to the dominant white spotting locus (W) of the mouse. W mutations affect melanogenesis, gametogenesis, and hematopoiesis during development and in adult life. In order to determine the regulation of the c-kit gene in cell differentiation, we investigated its expression during the differentiation of F9 cells. Undifferentiated F9 cells and F9 cells treated with retinoic acid (RA) alone or dbcAMP alone showed little expression of c-kit mRNA if any. The subsequent addition of dbcAMP to F9 cells treated with RA markedly increased the expression of c-kit mRNA. Furthermore, the effect of dbcAMP on c-kit expression is reversible. In differentiated cells treated with RA, c-kit gene expression is induced by agents such as forskolin or theophylline, which are known to elevate cellular cAMP level. These results indicate that the expression of the c-kit gene is regulated by the level of intracellular cAMP in differentiated F9 cells induced by RA.

Inhibition of DNA synthesis causes stem cell differentiation: induction of teratocarcinoma F9 cell differentiation with nucleoside analogues of DNA-synthesis inhibitors and their inducing abilities counterbalanced specifically by normal nucleosides

Nucleoside analogues inhibiting DNA synthesis can induce cell differentiation in teratocarcinoma cells. We have examined how their abilities to induce F9 cell differentiation were specifically counterbalanced by their corresponding normal nucleosides. We have also compared the differentiation inducing ability of the wild type F9 cells with that of its thymidine kinase-less mutant using plasminogen activator, as a differentiation marker, which is expressed at a very early stage of endodermal cell differentiation and can be assayed quantitatively. The results obtained were clearly explainable by the conventionally accepted action mechanisms of the nucleoside analogues, thus strongly suggesting that their abilities to induce cell differentiation were direct consequences of the inhibition of DNA synthesis; thus this confirms the notion that a close association exists between the inhibition of DNA synthesis and the induction of teratocarcinoma stem cell differentiation.

THE KINETICS OF INDUCTION OF HOX1.6 AND C-JUN MRNA DURING THREE DIFFERENT WAYS OF INDUCING DIFFERENTIATION IN TERATOCARCINOMA F9 CELLS

SummaryChanges in Hox1.6 and c-jun gene expression were examined upon F9 cell differentiation that was induced by three independent methods: a drug treatment with retinoic acid (RA), that with sodium butyrate (NaB), and a genetic approach using thets mutant. To obtain further information on the mechanism of teratocarcinoma cell differentiation we have examined the kinetics of the induction of Hox1.6 and c-jun mRNA whose gene products have been demonstrated to have specific roles in gene regulation. Expression of Hox1.6 mRNA was induced more rapidly than c-jun mRNA by all the above three inducing methods. Furthermore, protein synthesis was not required for the induction of Hox1.6 mRNA as well as of c-jun mRNA synthesis in all three methods. The data suggested that the transcriptional increase in the Hox1.6 mRNA was a primary response and could play an important role in F9 cell differentiation.

Induction of teratocarcinoma F9 cell differentiation with cis-diammine dichloroplatinum(II) (CDDP)

cis-Diammine dichloroplatinum(II) (CDDP) is the salt of a platinum compound which has been noted to have a wide spectrum of activity against malignant disorders. We have studied the effects of CDDP on embryonal carcinoma F9 cell differentiation. In the presence of this agent in vitro, the cells showed rapid morphological changes, a marked increase in the mRNA expression of various differentiation markers accompanied by a loss of tumorigenicity. These results indicate that the differentiation of F9 cells is induced with CDDP.

Isolation of mutants showing temperature-sensitive cell growth from embryonal carcinoma cells: Control of stem cell differentiation by incubation temperatures

Embryonal carcinoma(EC) cells, the undifferentiated stem cells of teratocarcinomas, have many properties in common with pluripotent embryonic cells, and thus provide an excellent system for studying the early events involved in embryonic development and stem cell differentiation. We have isolated three novel mutants with temperature-sensitive(ts) cell growth that were able to differentiate at a non-permissive temperature for cell growth. These mutations affect the progression of the cell cycle, leading to the transient accumulation of cells in a specific phase, the S phase, of the cell cycle, which is likely to be the primary cause of stem cell differentiation of EC cells at non-permissive temperature. Isolation of these mutants strongly supports the notion that there is a close association between the inhibition of DNA synthesis and EC cell differentiation.

F9 Cells Can be Differentiated toward Two Distinct, Mutually Exclusive Pathways by Retinoic Acid and Sodium Butyrate

Both retinoic acid (RA) and sodium butyrate (NaB) induce differentiation in embryonal carcinoma F9 cells. Phenotypic changes caused by RA are irreversible, whereas those of NaB are rapid and reversible. In this study, we investigated the effects of combinations of these two agents on F9 cell differentiation and showed that RA had no effect on the cells induced to differentiate with NaB and vice versa. Thus, F9 cells are induced to differentiate along two distinct pathways which are mutually exclusive.