A role for p21 (WAF1) in the cAMP-dependent differentiation of F9 teratocarcinoma cells into parietal endoderm

Combined treatment of teratocarcinoma F9 cells with retinoic acid and dibutyryl-cAMP induces the differentiation into cells with a phenotype resembling parietal endoderm. We show that the levels of cyclin-dependent kinase inhibitor p21/WAF1/Cip1 (p21) protein and mRNA are dramatically elevated at the end of this differentiation, concomitantly with the appearance of p21 in the immunoprecipitated CDK2-cyclin E complex. The induction of differentiation markers could not be achieved by expression of ectopic p21 alone and still required treatment with differentiation agents. Clones of F9 cells transfected with sense or antisense p21 cDNA constructs revealed, upon differentiation, upregulated levels of mRNA for thrombomodulin, a parietal endoderm-specific marker, or increased fraction of cells in sub-G1 phase of the cell cycle, respectively. Consistent with this observation, whereas p21 was strictly nuclear in undifferentiated cells, a large proportion of differentiated cells had p21 localized also in the cytoplasm, a site associated with the antiapoptotic function of p21. Furthermore, p21 activated the thrombomodulin promoter in transient reporter assays and the p21 mutant defective in binding to cyclin E was equally efficient in activation. The promoter activity in differentiated cells was reduced by cotransfection of p21-specific siRNA or antisense cDNA. Coexpression of p21 increased the activity of the GAL-p300(1-1303) fusion protein on the GAL sites-containing TM promoter. This implies that p21 might act through a derepression of the p300 N-terminal-residing repression domain, thereby enhancing the p300 coactivator function. As differentiation of F9 cells into parietal endoderm-like cells requires the cAMP signaling, the results together suggest that the cyclin-dependent kinase inhibitor p21 may promote specifically this pathway in F9 cells.     

Effect of 5-azacytidine treatment on mouse embryonal carcinoma cells

Several properties of embryonal carcinoma (EC) cell lines, such as multipotent PCC4-aza-1 cells and nullipotent F9 cells originating from murine teratocarcinoma cells, were examined after treatment with 5-azacytidine, which produces undermethylated DNA. Drug-treated PCC4-aza-1 cells exhibited morphological changes and differentiated, whereas azacytidine-treated F9 cells displayed no detectable morphological change. After treatment with 5 azacytidine, PCC4-aza-1 cells, whether or not they differentiated, as well as F9 cells, became permissive for polyoma even though both cell types are usually resistant to polyoma. In contrast, only the differentiated azacytidine-treated PCC4-aza-1 cells became sensitive to SV40 infection, i.e., synthesized T antigen, despite the resistance normally shown by such cells to this viral infection. In some PCC4-aza-1 and F9 cells, drug treatment induced expression of H2 antigen but did not derepress plasminogen activator synthesis. These results suggest that undermethylation of certain cellular genes in PCC4-aza-1 and F9 cells is correlated with the establishment of Py permissivity, SV40 sensitivity, H2 antigen expression, and the triggering of a differentiation process. The relationship between the expression of these characters and differentiation is discussed.     

Requirement of RBP9, a Drosophila Hu homolog, for regulation of cystocyte differentiation and oocyte determination during oogenesis

The Drosophila RNA binding protein RBP9 and its Drosophila and human homologs, ELAV and the Hu family of proteins, respectively, are highly expressed in the nuclei of neuronal cells. However, biochemical studies suggest that the Hu proteins function in the regulation of mRNA stability, which occurs in the cytoplasm. In this paper, we show that RBP9 is expressed not only in the nuclei of neuronal cells but also in the cytoplasm of cystocytes during oogenesis. Despite the predominant expression of RBP9 in nerve cells, mutational analysis revealed a female sterility phenotype rather than neuronal defects for Rbp9 mutants. The female sterility phenotype of the Rbp9 mutants resulted from defects in oogenesis; the lack of Rbp9 activity caused the germarium region of the mutants to be filled with undifferentiated cystocytes. RBP9 appears to stimulate cystocyte differentiation by regulating the expression of bag-of-marbles (bam) mRNA, which encodes a developmental regulator of germ cells. RBP9 protein bound specifically to bam mRNA in vitro, which is required for cystocyte proliferation, and the number of cells that expressed BAM protein was increased 5- to 10-fold in the germarium regions of Rbp9 mutants. These results suggest that RBP9 protein binds to bam mRNA to down regulate BAM protein expression, which is essential for the initiation of cystocyte differentiation into functional egg chambers. In hypomorphic Rbp9 mutants, cystocytes differentiated into egg chambers; however, oocyte determination and positioning were perturbed. Therefore, the concentrated localization of RBP9 protein in the oocyte of the early egg chambers may be required for proper oocyte determination or positioning.     

Cell type-specific expression of nuclear lamina proteins during development of Xenopus laevis

The cell type-specific expression of the major nuclear lamina polypeptides ("lamins") during development of Xenopus was studied using two monoclonal antibodies (L(0)46F7: specific for LIII, the single lamin of oocytes; PKB8: specific for LI and LII of some somatic cells). In the oocyte, LIII localizes in the nuclear polymer, but upon nuclear envelope breakdown it is solubilized to a form sedimenting at 9 S. In early embryos, LIII contributes to nuclear lamina formation until its depletion. Correspondingly, LI and LII begin to be expressed at a specific point in embryogenesis and appear to be integrated with LIII into a common lamina structure. Later in development, LIII reappears as a prominent nuclear lamina protein but only in certain cells (neurons, muscle cells, and diplotene oocytes). We conclude that amphibian lamins represent a family of proteins expressed in relation to certain programs of cell differentiation.     

Characterization of cloned sequences complementary to F9 cell double-stranded RNA and their expression during differentiation

In a cDNA library prepared from the RNA of cultured murine F9 teratocarcinoma cells, we identified sequences exhibiting strong hybridization to double-stranded RNA (dsRNA) of F9 cells but weak hybridization to mouse liver dsRNA. Northern-blot hybridization of RNA extracted from F9 cells with or without treatment with retinoic acid revealed differences in the expression of some of these sequences in undifferentiated and differentiated cells. As shown by Southern-blot hybridization experiments, these differences of expression were not related to a gross rearrangement of the corresponding genomic DNA sequences of the differentiated cells. When RNA from F9 cells was used, one of the cloned dsRNA-related sequences selected mRNA which was translated in vitro to a polypeptide with an Mr of 24,000; the level of this mRNA was reduced in F9 cells that had been treated with retinoic acid. Our results show that the differentiation of F9 cells induced by retinoic acid results in the differential expression of some middle-repetitive sequences.     

The vimentin promoter as a tool to analyze the early events of retinoic acid-induced differentiation of cultured embryonal carcinoma cells

The vimentin gene encodes an intermediate filament protein expressed in the parietal endoderm, mesodermal, and early neural cells in vivo but by most in vitro-cultured cells regardless of their embryonic origin. Here we show that the vimentin gene promoter is very active in F9 embryonal carcinoma cells and increases in activity during differentiation. Using a series of 5'-deletion mutants, we provide evidence that the regions of the promoter involved in F9 cell activity are different from those previously demonstrated to be active in differentiated cell lines. Furthermore, we show that in differentiating F9 cells the activities of two different regions of the promoter are significantly enhanced. A distal region (-1710/-957) appears to contain functional binding sites for the murine Hox-A5 homeoprotein as demonstrated by band shift and footprinting experiments. A proximal region (-140/-78) contains a 30-bp repetitive sequence found in other genes activated during differentiation of F9 cells. Using band shift assays and methylation interference, we present evidence that a sequence-specific single-stranded DNA-binding protein(s) specifically interacts with the minus strand of the 30-bp sequence.     

Epigenetic marks in somatic chromatin are remodelled to resemble pluripotent nuclei by amphibian oocyte extracts

Reprogramming pluripotency after nuclear transplantation shows that molecules in oocytes can remodel somatic chromatin to a stem cell state. Here we report on an ex-ovo system using axolotl oocyte extracts to remodel epigenetic marks of somatic chromatin. Molecules present in axolotl oocyte extracts induce the reduction of the overall levels of H3K9me3, HP1α, and DNA methylation of somatic cells, and they increase the levels of H3K9ac. The levels of signal intensity detected in treated differentiated cells resemble those detected in embryonic stem cells, which are, in contrast, unaffected by these extracts. Analysis of specific genome sequences shows that somatic cells exposed to oocyte extracts undergo demethylation of LINE-1 repeats but Major Satellite repeats and the imprinted gene H19 remain unchanged. In addition, they induce demethylation of the Oct-4 promoter. Finally, the kinetics of activation of Oct-4 and Nanog expression from MEF nuclei treated in extracts suggests that these genes are subject to different levels of epigenetic control. The results demonstrate that axolotl oocyte extracts are a useful tool for studying epigenetic remodelling of somatic cells to a stem cell configuration, and for elucidating oocyte specific mechanisms of nuclear reprogramming.     

Negative transcriptional regulatory element that functions in embryonal carcinoma cells.

We have cloned the polyomavirus mutant fPyF9, which persists in an episomal state in F9 embryonal carcinoma cells (K. Ariizumi and H. Ariga, Mol. Cell. Biol. 6:3920-3927, 1986). fPyF9 carries three copies of exogenous sequences, the prototype of which is a 21-base-pair repeat (box DNA), in the region of the enhancer B domain of wild-type polyomavirus DNA. The consensus sequence, GCATTCCATTGTT, is 13 base pairs long. The box DNA inserted into fPyF9 appeared to come from a cellular sequence and was present in many kinds of DNAs, including F9 chromosomal DNA. The biological function of box DNA was analyzed by chloramphenicol acetyltransferase expression assays, using chimeric plasmids containing box DNA conjugated with simian virus 40 promoter elements. The results showed that box DNA repressed the activities both of the simian virus 40 promoter and enhancer only in transfected undifferentiated F9 cells and not in differentiated LTK- cells. Box DNA functioned independently of orientation and position with respect to the promoter in an enhancerlike manner, although the effect of box DNA was opposite that of the enhancer. The XhoI linker insertion into the consensus sequences of box DNA abolished the repression activity, and the protein(s) recognizing the consensus sequences was identified only in F9 cells, not in L cells. These analyses suggest that box DNA may be a negative regulatory element that functions in undifferentiated cells.     

Immunohistochemical demonstration of histone H1<Superscript>0</Superscript> in human breast carcinoma

Histone H1(0) is a linker histone subvariant present in tissues of low proliferation rate. It is supposed to participate in the expression and maintenance of the terminal differentiation phenotype. The aim of this work was to study histone H1(0) distribution in human breast carcinoma and its relationship with the processes of proliferation and differentiation. Most of the cells in carcinomas of moderate and high level of differentiation expressed histone H1(0) including cells invading connective and adipose tissues. In low differentiated tumours, the number of H1(0) expressing cells was considerably lower. Staining of myoepithelial cells, when seen, and of stromal fibroblasts was variable. The metastatic malignant cells in the lymph nodes also accumulated H1(0) but lymphocytes were always negative. All immunopositive malignant cells exhibited signs of polymorphism. Double H1(0)/Ki-67 staining showed that the growth fraction in more differentiated tumours belonged to the H1(0)-positive cells, while in poorly differentiated carcinomas it also included a cell subpopulation not expressing H1(0). If expressed, p27Kip1 was always found in H1(0)-positive cells. These findings are inconsistent with the widespread view that histone H1(0) is expressed only in terminally differentiated cells. Rather, they suggest that the protein is expressed in cells in a prolonged intermitotic period irrespective of their level of differentiation. Double H1(0)/Ki-67 immunostaining could be a useful tool in studying the growth fraction in tumours.     

Early increase in histone H1(0) mRNA during differentiation of F9 cells to parietal endoderm.

We have isolated and characterized cDNA clones coding for the H1 histone subtype H1(0) in mouse teratocarcinoma cells. The mRNA is 2100 nt long and contains a coding sequence which is highly related to that of the human H1(0) gene. Using this cDNA as a probe, we have shown that, in comparison to undifferentiated F9 cells, differentiated F9 teratocarcinoma cells contain large amounts of H1(0) mRNA. This increase takes place very early during differentiation and does not correlate with changes in the rate of cell division. This indicates that the accumulation of H1(0) mRNA is not the result of reduced proliferation. Most likely on the contrary, the increase in the amount of H1(0) and the resulting effects on the formation of high order chromatin structures are parts of the differentiation program induced in F9 cells.     

Induction of alpha-fetoprotein synthesis in differentiating F9 teratocarcinoma cells is accompanied by a genome-wide loss of DNA methylation.

F9 teratocarcinoma cells can be grown as monolayers or aggregates, and upon treatment with retinoic acid they will differentiate into parietal or visceral endoderm, respectively. Visceral endoderm specifically synthesizes alpha-fetoprotein and albumin mRNAs, which are not found in parietal endoderm. In contrast, both endoderms produce enhanced levels of the major histocompatibility antigen (H2) mRNA compared with F9 cells. F9 cells contain highly methylated DNA as judged by restriction enzyme digestion. However, upon differentiation into visceral endoderm, there is a genome-wide loss of methylation in induced, silent, and constitutively expressed genes. Experiments in which methylation loss is induced via the methyltransferase inhibitor 5-azacytidine result in no induction of alpha-fetoprotein mRNA and no morphological differentiation, suggesting that methylation loss alone is not sufficient to induce the visceral endoderm phenotype. Likewise, 5-azacytidine treatment of differentiated cells does not result in enhanced expression of alpha-fetoprotein mRNA. However, the patterns of loss of DNA methylation at all sites examined after differentiation or 5-azacytidine treatment were remarkably similar, suggesting that the two occur by a similar mechanism, the inhibition of DNA methyltransferase activity. These results argue that the specificity for methylation loss at a given site is an inherent property of aggregated F9 cell chromatin. This system provides a model for studying a tissue-specific change in DNA methylation upon differentiation.     

Isolation and characterization of the cDNAs corresponding to mRNAs abundant in undifferentiated mouse embryonal teratocarcinoma stem cells, but not in differentiated mouse parietal endoderm cells

As retinoic acid (RA) and dibutyryl cAMP (cAMP) treatment induces differentiation of mouse teratocarcinoma F9 cells into parietal endoderm cells in vitro, we initiated studies on the molecular mechanisms underlying early mammalian cell differentiation in this system. We constructed cDNA libraries on the poly(A)+RNAs extracted from the undifferentiated F9 cells, and screened for cDNA sequences expressed abundantly in F9 cells, but not in terminally differentiated mouse parietal endoderm PYS-2 cells. Six different cDNA clones were isolated and characterized. The levels of RNAs hybridizable to these clones were at most 5 to 24% in the PYS-2 cells when compared with those in the undifferentiated F9 cells. The six clones were classified into two groups on the basis of their responses to the RA and cAMP treatment. In F9 cells, the levels of RNAs hybridizable to the first group, which contained four clones, were decreased within 72 h after the addition of RA and cAMP, while those of the second group, which contained the remaining two clones, did not decrease significantly. One of the first group clones, named pF9-1, corresponded to the mouse "early transposon-like elements" and another, named pF9-4, hybridized to multi-size RNAs extracted from the undifferentiated F9 cells. The mouse genomic DNA sequences hybridizable to pF9-4 were repeated approximately 5,000 times, and comprise a new gene family, the expression of which is developmentally regulated in mouse F9 cells.