Undifferentiated F9 Research Articles

The influence of sample preprocessing on in situ identification of 5-methylcytosine in metaphase chromosomes and interphase nuclei

Qualitative and quantitative analysis of DNA methylation in situ at the level of cells, chromosomes, and the chromosomal domain is extremely important in diagnosis and treatment of various pathologies, as well in studies of aging and the effects of environmental factors. Yet, the questions remain unresolved of whether the detectable in situ methylation patterns correspond to the actual DNA methylation per se and/or reflect the accessibility of DNA to antibodies, which depends on the structural features of chromatin and chromosome condensation. Thus, this phenomenon can result in an incorrect determination of the real DNA methylation pattern. In order to eliminate this disadvantage to the extent possible, we modified the commonly used methodology of in situ detection methylcytosine by means of monoclonal antibodies. In this study, we show that the efficiency of immunofluorescent labeling for 5-methylcytosin in centromeric heterochromatin, chromosome arms and sister chromatids is significantly affected by the conditions of pretreatment of chromosome preparations. We used undifferentiated murine embryonic F9 cells to show that variations in the conditions of storage of chromosome preparations can lead to a sharp reduction of labeling intensity and even disappearance of the fluorescence signal in centromeric heterochromatin. Using the developed method, we discovered asymmetric methylation of sister chromatids in F9 cells and in human peripheral blood lymphocytes. This phenomena can lead to asymmetric cell division and asymmetric transcriptional status in daughter cells. Thus, the modified methodology for detection of 5-methyl cytosine in situ can provide for a more precise assessment of methylation of chromosomes and chromosomal regions.

Redox Regulation of Canonical Wnt Signaling Affects Extraembryonic Endoderm Formation

Retinoic acid (RA) induces mouse F9 cells to form primitive endoderm (PrE) and increased levels of reactive oxygen species (ROS) accompany differentiation. ROS are obligatory for differentiation and while H2O2 alone induces PrE, antioxidants attenuate the response to RA. Evidence shows that ROS can modulate the Wnt/β-catenin pathway and in this study, we show that extraembryonic endoderm formation is dependent on the redox state of nucleoredoxin (NRX). In undifferentiated F9 cells, NRX interacted with dishevelled 2 (Dvl2) and while this association was enhanced under reduced conditions, it decreased following H2O2 treatment. Depleting NRX levels caused morphological changes like those induced by RA, while increasing protein kinase A activity further induced these PrE cells to parietal endoderm. Reduced NRX levels also correlated to an increase in T-cell-factors-lymphoid enhancer factors-mediated transcription, indicative of canonical Wnt signaling. Together these results indicate that a mechanism exists whereby NRX maintains canonical Wnt signaling in the off state in F9 cells, while increased ROS levels lift these constraints. Dvl2 no longer bound to NRX is now positioned to prime the Wnt pathway(s) required for PrE formation.

Extracellular syntaxin4 triggers the differentiation program in teratocarcinoma F9 cells that impacts cell adhesion properties

The proteins in the syntaxin family are known to mediate fusion of cytoplasmic vesicles to the target membrane, yet subpopulations of certain syntaxins, including syntaxin4, translocate across the cell membrane in response to external stimuli. Here, we show that extracellularly presented syntaxin4 impacts cell behavior and differentiation in teratocarcinoma F9 cells. While undifferentiated F9 cells extruded a small subpopulation of extracellular syntaxin4 at the lateral cell membrane, the induction of differentiation with all-trans retinoic acid (RA) abolished this localized expression pattern. We found that the cells that were stimulated in a non-directional fashion by extracellular syntaxin4 displayed a flattened shape and retained a substrate-bound morphology even under a long-term, serum-starved cultivation. Such a cellular response was also elicited by a circular peptide composed of the potential functional core of syntaxin4 (AIEPQK; amino acid residues 103~108) (ST4n1). While the proliferation and metabolism were not affected in these cells, cell-cell interaction became weakened and the expression of vinculin, a regulator of both intercellular and cell-substrate adhesion molecules, was altered. We also found that the expressions of several differentiation markers were up-regulated in cells stimulated with extracellular syntaxin4 and that syntaxin3, another family member, was most prominent. Intriguingly, forced expression of syntaxin3 induced the spread morphology in F9 cells, indicating that syntaxin3 partly mediates the function of extracellular syntaxin4. These results demonstrate the involvement of a non-directional stimulation of extracellular syntaxin4 in the functional and morphological differentiation of F9 cells.

Wnt6 induces the specification and epithelialization of F9 embryonal carcinoma cells to primitive endoderm

Epithelial-to-mesenchymal transitions (EMTs) play key roles in the normal development of an organism as well as its demise following the metastasis of a malignant tumour. An EMT during early mouse development results in the differentiation of primitive endoderm into the parietal endoderm that forms part of the parietal yolk sac. In the embryo, primitive endoderm develops from cells in the inner cell mass, but the signals that instruct these cells to become specified and adopt an epithelial fate are poorly understood. The mouse F9 teratocarcinoma cell line, a model that can recapitulate the in vivo primitive to parietal endoderm EMT, has been used extensively to elucidate the signalling cascades involved in extraembryonic endoderm differentiation. Here, we identified Wnt6 as a gene up-regulated in F9 cells in response to RA and show that Wnt6 expressing cells or cells exposed to Wnt6 conditioned media form primitive endoderm. Wnt6 induction of primitive endoderm is accompanied by β-catenin and Snail1 translocation to the nucleus and the appearance of cytokeratin intermediate filaments. Attenuating glycogen synthase kinase 3 activity using LiCl gave similar results, but the fact that cells de-differentiate when LiCl is removed reveals that other signalling pathways are required to maintain cells as primitive endoderm. Finally, Wnt6-induced primitive endodermal cells were tested to determine their competency to complete the EMT and differentiate into parietal endoderm. Towards that end, results show that up-regulating protein kinase A activity is sufficient to induce markers of parietal endoderm. Together, these findings indicate that undifferentiated F9 cells are responsive to canonical Wnt signalling, which negatively regulates glycogen synthase kinase 3 activity leading to the epithelialization and specification of primitive endoderm competent to receive additional signals required for EMT. Considering the ability of F9 cells to mimic an in vivo EMT, the identification of this Wnt6–β-catenin–Snail signalling cascade has broad implications for understanding EMT mechanisms in embryogenesis and metastasis.

Yin Yang 1 Physically Interacts with Hoxa11 and Represses Hoxa11-dependent Transcription

Yin Yang 1 (YY1) plays an indispensable role in embryonic development. YY1 contains an evolutionarily conserved, 22-amino acid segment, the PHO homology region (PHR), which is located within its central domain (spacer) and has been shown previously to participate in the recruitment of Polycomb group of proteins and in YY1-mediated transcription. In this report, we show that the PHR physically interacts with several Abd-B-type Hox proteins. Although ectopic expression of Hoxa11 enhanced target promoter activity, overexpression of YY1 repressed this effect, which was abrogated by YY1 siRNA and the histone deacetylase inhibitor trichostatin A. We have further demonstrated that this suppression effect was the result of YY1-dependent recruitment of HDAC2 to the Hoxa11 target promoter. Taken together, our findings show that YY1 represses Hoxa11-dependent transcription via interactions with the Hox proteins and HDAC recruitment, providing a link between an Abd-type Hox protein and a Polycomb group protein at the level of direct protein-protein interactions. These findings not only provide a novel insight into YY1 function but also identify a new regulation of homeotic protein-mediated transcriptional regulation in general.

Regulation of the Pluripotency Marker Rex-1 by Nanog and Sox2

Rex-1 (Zfp-42) is a known marker for undifferentiated embryonic stem cells and teratocarcinoma cells. However, the mechanism by which Rex-1 is regulated in pluripotent cells remains unresolved. Here we report that Nanog, an Nk-2 homeodomain protein known for its role in maintaining stem cell pluripotency, is a transcription activator for the Rex-1 promoter. Knockdown of Nanog in embryonic stem cells resulted in a reduction of Rex-1 expression, whereas forced expression of Nanog in P19 stimulated Rex-1 expression. Employing a Rex-1 reporter, we demonstrate that Nanog transactivates Rex-1 directly. Serial deletion studies mapped the Nanog-responsive element between -187 and -286 of the Rex-1 promoter. Although Oct-3/4 and Sox2 can both transactivate Rex-1 promoter, only Sox2 cooperates with Nanog in up-regulating Rex-1. Furthermore, we demonstrate that the C terminus of Nanog is responsible for transactivating the Rex-1 promoter, a function that can be substituted for by a viral transactivator Vp16 efficiently in NIH3T3 cells but less so in P19 cells. Taking these findings together, we conclude that Rex-1 is a direct target of Nanog, which is augmented by Sox2 and Oct-3/4.

Behavior of tight-junction, adherens-junction and cell polarity proteins during HNF-4α-induced epithelial polarization

We previously reported that expression of tight-junction molecules occludin, claudin-6 and claudin-7, as well as establishment of epithelial polarity, was triggered in mouse F9 cells expressing hepatocyte nuclear factor (HNF)-4alpha [H. Chiba, T. Gotoh, T. Kojima, S. Satohisa, K. Kikuchi, M. Osanai, N. Sawada. Hepatocyte nuclear factor (HNF)-4alpha triggers formation of functional tight junctions and establishment of polarized epithelial morphology in F9 embryonal carcinoma cells, Exp. Cell Res. 286 (2003) 288-297]. Using these cells, we examined in the present study behavior of tight-junction, adherens-junction and cell polarity proteins and elucidated the molecular mechanism behind HNF-4alpha-initiated junction formation and epithelial polarization. We herein show that not only ZO-1 and ZO-2, but also ZO-3, junctional adhesion molecule (JAM)-B, JAM-C and cell polarity proteins PAR-3, PAR-6 and atypical protein kinase C (aPKC) accumulate at primordial adherens junctions in undifferentiated F9 cells. In contrast, CRB3, Pals1 and PATJ appeared to exhibit distinct subcellular localization in immature cells. Induced expression of HNF-4alpha led to translocation of these tight-junction and cell polarity proteins to beltlike tight junctions, where occludin, claudin-6 and claudin-7 were assembled, in differentiated cells. Interestingly, PAR-6, aPKC, CRB3 and Pals1, but not PAR-3 or PATJ, were also concentrated on the apical membranes in differentiated cells. These findings indicate that HNF-4alpha provokes not only expression of tight-junction adhesion molecules, but also modulation of subcellular distribution of junction and cell polarity proteins, resulting in junction formation and epithelial polarization.

SOX7 and SOX17 Regulate the Parietal Endoderm-specific Enhancer Activity of Mouse Laminin α1 Gene

Laminin-1 is the major component of embryonic basement membrane and consists of alpha1, beta1, and gamma1 chains. The expression of laminin-1 is induced in mouse F9 embryonal carcinoma cells upon differentiation into parietal endoderm cells. We recently identified a parietal endoderm-specific enhancer in the mouse laminin alpha1 (Lama1) gene and showed that Sp1/Sp3 and YY1 transcription factors were involved in the enhancer activity. Although here we identified that NF-Y binds to the enhancer sequence between Sp1/Sp3- and YY1-binding sites, all these transcription factors are ubiquitously expressed and thus are not sufficient to explain parietal endoderm-specific enhancer activity. In the present study, we further showed that SOX7 and SOX17 are involved in the regulation of parietal endoderm-specific enhancer activity of the mouse Lama1 gene. Northern blot analysis revealed that the steady-state levels of mouse Sox7 and Sox17 mRNAs increased in parallel with that of Lama1 mRNA during the differentiation of F9 cells. Both SOX7 and SOX17 markedly trans-activated the transcription of the Lama1 enhancer-reporter construct in undifferentiated F9 cells in a manner dependent on high mobility group box-mediated DNA binding. Electrophoretic mobility shift assays and mutational analyses revealed that SOX7 and SOX17 bound specifically to two SOX-binding sites within the Lama1 enhancer, and that these SOX-binding sites functioned synergistically to confer the trans-activation by SOX7 and SOX17. Furthermore, this trans-activation was dependent on the integrity of the binding sites for Sp1/Sp3 and NF-Y located at upstream of the two SOX-binding sites. These results indicate that the transcription of the mouse Lama1 gene during the differentiation of F9 cells is controlled by a combination of the actions of the ubiquitous factors, Sp1/Sp3 and NF-Y, and the parietal endoderm-specific factors, SOX7 and SOX17.

A blockade in Wnt signaling is activated following the differentiation of F9 teratocarcinoma cells

Aberrant activation of the Wnt signaling pathway is a common event in human tumor progression. Wnt signaling has also been implicated in maintaining a variety of adult and embryonic stem cells by imposing a restraint to differentiation. To understand the effect of Wnt signaling on the differentiation of epithelial cells, we used mouse teratocarcinoma F9 cells as a model. The F9 cells can be differentiated into visceral endoderm (VE) resembling absorptive columnar epithelial cells. We performed comparative gene expression analysis on retinoic acid-differentiated and undifferentiated F9 cells and confirmed that markers of VE and intestinal epithelium were induced upon differentiation. The induction of these markers by retinoic acid was reduced in the presence of Wnt, although Wnt alone did not change their expression. This suggests that Wnt signaling inhibited the differentiation of F9 cells by altering gene expression. This inhibition was also reflected in the morphology of the F9 cells as their apical–basal polarity was disrupted by inclusion of Wnt during differentiation. These results support a model in which Wnt modulates the expression of genes required for normal terminal differentiation of the stem cells. However, it follows that progenitor cells must escape from Wnt signaling to attain the differentiated state. Accordingly, we found that differentiated F9 cells no longer responded to Wnt and that a blockade in Wnt signaling occurred upstream of Axin. Consistent with this, Wnt negative regulators, such as Dickkopf-1 and Disabled-2, were induced upon the differentiation of F9 cells. We propose that a similar system to produce Wnt inhibitors regulates homeostasis of certain stem cell compartments in vivo.

Identification of an Upstream Enhancer in the Mouse Lamininα1 Gene Defining Its High Level of Expression in Parietal Endoderm Cells

Laminin-1 is the major component of the embryonic basement membrane and consists of alpha1, beta1, and gamma1 chains. The expression of laminin-1 is induced in mouse F9 embryonal carcinoma cells upon differentiation into parietal endoderm through transcriptional up-regulation of the genes encoding these subunits. Here, we identified a 435-bp enhancer in the 5'-flanking region of the mouse laminin alpha1 (LAMA1) gene that activated its transcription in a differentiation-dependent manner. This enhancer was also active in PYS-2 parietal yolk sac-derived cells but not in NIH/3T3 fibroblasts, indicating that it was a parietal endoderm-specific enhancer. This enhancer was also active in Engelbreth-Holm-Swarm (EHS) tumor-derived cells characterized by excessive production of laminin-1 and other basement membrane components, suggesting that EHS tumors have a transcriptional control mechanism similar to that of parietal endoderm cells. Electrophoretic mobility shift analyses revealed four protein binding sites (PBS1-PBS4) in the 435-bp region. However, these DNA-binding proteins were detected not only in parietal endoderm cells (i.e. differentiated F9 cells, PYS-2 cells, and EHS tumor-derived cells) but also in undifferentiated F9 cells and NIH/3T3 cells. Mutational analyses revealed that three of these binding sites (PBS2, PBS3, and PBS4) function synergistically to confer the parietal endoderm-specific enhancer activity. The proteins binding to PBS2 and PBS4 were identified as the Sp1/Sp3 family of transcription factors and YY1, respectively.

Ras/MAPK Pathway Confers Basement Membrane Dependence upon Endoderm Differentiation of Embryonic Carcinoma Cells

The formation of extraembryonic endoderm is one of the earliest steps in the differentiation of pluripotent cells of the inner cell mass during the early stages of embryonic development. The primitive endoderm cells and the derived parietal and visceral endoderm cells gain the capacity to produce collagen IV and laminin. The deposition of these components results in the formation of basement membrane and epithelium of the endoderm, with polarized cells covering the inner surface of the blastocoels. We used retinoic acid-induced endoderm differentiation of stem cell-like F9 embryonic carcinoma cells to study the role of the Ras pathway and its regulation in the formation of the visceral endoderm. Upon endoderm differentiation of F9 cells induced by retinoic acid, c-Fos expression, the downstream target of the Ras pathway, is suppressed by uncoupling Elk-1 phosphorylation/activation to MAPK activity. However, attachment to matrix gel greatly enhances the activation of MAPK in endoderm cells but not in undifferentiated F9 cells. Enhanced MAPK activation as a result of contact with basement membrane is able to compensate for reduced Elk-1 phosphorylation and c-Fos expression. We conclude that endoderm differentiation renders the activation of the Ras pathway basement membrane dependent, contributing to the epithelial organization of the visceral endoderm.

Retinoic acid induces parietal endoderm but not primitive endoderm and visceral endoderm differentiation in F9 teratocarcinoma stem cells with a targeted deletion of the Rex-1 (Zfp-42) gene

Cultured murine F9 teratocarcinoma stem cells resemble pluripotent stem cells of the inner cell mass of the mouse blastocyst and, depending upon their treatment, can be induced to differentiate along the primitive endoderm, the parietal endoderm (PE), or the visceral endoderm (VE) pathway. The Rex-1 gene encodes a zinc finger family transcription factor which is expressed at high levels in undifferentiated F9 stem cells, embryonic stem cells, and in other types of stem cells. To examine whether the Rex-1 protein plays a role in F9 cell differentiation, homologous recombination was employed to generate F9 cell lines which lack both alleles of Rex-1. F9 wild type cells in monolayer culture require both retinoic acid and cyclic AMP analogs to differentiate into PE, whereas the F9 Rex-1 −/− cells differentiate into PE, as assessed by several molecular markers, including thrombomodulin and laminin B1, in the presence of RA alone. The F9 Rex-1 −/− cells do not completely differentiate into VE after RA treatment in aggregate culture; they do not express alpha-fetoprotein, a definitive marker of VE differentiation. These results indicate that the Rex-1 transcription factor regulates the differentiation of F9 stem cells along several distinct cell lineages found in the early embryo.

JDP2, a repressor of AP-1, recruits a histone deacetylase 3 complex to inhibit the retinoic acid-induced differentiation of F9 cells.

Up-regulation of the c-jun gene is a critical event in the retinoic acid (RA)-mediated differentiation of embryonal carcinoma F9 cells. Activating transcription factor 2 (ATF-2) and p300 cooperate in the activation of transcription of the c-jun gene during the differentiation of F9 cells. We show here that the overexpression of Jun dimerization protein 2 (JDP2), a repressor of AP-1, inhibits the transactivation of the c-jun gene by ATF-2 and p300 by recruitment of the histone deacetylase 3 (HDAC3) complex, thereby repressing the RA-induced transcription of the c-jun gene and inhibiting the RA-mediated differentiation of F9 cells. Moreover, chromatin immunoprecipitation assays showed that the JDP2/HDAC3 complex, which binds to the differentiation response element within the c-jun promoter in undifferentiated F9 cells, was replaced by the p300 complex in response to RA, with an accompanying change in the histone acetylation status of the chromatin, the initiation of transcription of the c-jun gene, and the subsequent differentiation of F9 cells. These results suggest that JDP2 may be a key factor that controls the commitment of F9 cells to differentiation and shed new light on the mechanism by which an AP-1 repressor functions.

Global gene expression patterns during differentiation of F9 embryonal carcinoma cells into parietal endoderm.

Expression levels of over 8,900 murine genes were examined, using cDNA microarrays, during the differentiation of F9 cells into parietal endoderm following exposure to retinoic acid/dibutyryl cAMP. Gene induction and repression over the time course exhibited a biphasic pattern consistent with a transition from undifferentiated F9 cells to primitive endoderm and finally parietal endoderm. A 6-h induction with retinoic acid/cAMP/cycloheximide resulted in 109 candidate immediate response genes. During a 9-day time course 516 genes were selected as being significantly induced/repressed. Several of these genes had been previously identified as having altered expression patterns in F9 cells undergoing differentiation by retinoic acid/cAMP. Functional characterization of these genes demonstrated that the majority were transcription factors while others included surface antigens and genes involved in intracellular transport. Cluster analysis, utilizing both a hierarchical algorithm and self-organizing map, resulted in very similar gene clusters. Our studies revealed an extremely complex set of interacting signals that decide between cell death, differentiation, cell cycle withdrawal, and ultimately the traits associated with the terminal differentiated parietal endoderm cell type. The sets of genes identified here can now be modulated in a rational way to try to understand their role in differentiation.

Adenovirus-Mediated Increase of HNF-3 Levels Stimulates Expression of Transthyretin and Sonic Hedgehog, Which Is Associated With F9 Cell Differentiation Toward the Visceral Endoderm Lineage

Retinoic acid-induced differentiation of mouse F9 embryonal carcinoma cells toward the visceral endoderm lineage is accompanied by increased expression of the Forkhead Box (Fox) transcription factors hepatocyte nuclear factor 3a (HNF-3alpha) and HNF-3beta, suggesting that they play a crucial role in visceral endoderm development. Retinoic acid stimulation results in a cascade of HNF-3 induction in which HNF-3alpha is a primary target for retinoic acid action and its increase is required for subsequent induction of HNF-3beta expression. Increased expression of HNF-3beta precedes activation of its known target genes, including transthyretin (TTR), Sonic hedgehog (Shh), HNF-1alpha, HNF-1beta, and HNF-4alpha. In order to examine whether increased HNF-3 expression is sufficient to induce expression of its downstream target genes without retinoic acid stimulation, we have used adenovirus-based expression vectors to increase HNF-3 protein levels in F9 cells. We demonstrate that adenovirus-mediated increase of HNF-3alpha levels in F9 cells is sufficient to induce activation of endogenous HNF-3beta levels followed by increased TTR and Shh expression. Furthermore, we show that elevated HNF-3beta levels stimulate expression of endogenous TTR and Shh without retinoic acid stimulation. Moreover, ectopic HNF-3 levels in undifferentiated F9 cells are insufficient to induce HNF-3alpha, HNF-1alpha, HNF-1beta, and HNF-4alpha expression, suggesting that their transcriptional activation required other regulatory proteins induced by the retinoic acid differentiation program. Finally, our studies demonstrate the utility of cell infections with adenovirus expressing distinct transcription factors to identify endogenous target genes, which are assembled with the appropriate nucleosome structure.

Expression of SET is modulated as a function of cell proliferation

We explored a biological role of SET as it relates to cell proliferation and differentiation. Immunohistochemical staining demonstrated that the expression of SET was ubiquitous and diffuse over the whole embryo on gestational day 15. At a later stage of development, SET was expressed at relatively lower levels and localized to specific tissues and cells. On embryonic day 19, specific SET immunoreactivity was found in the epithelium of skin, respiratory tract, intestine, and retina as well as in muscle and cartilage. In these cells SET was stained mostly in the nucleus, which was supported indirectly by nuclear transport of enhanced green fluorescence protein-SET fusion proteins in ECV304 endothelial cells. Set mRNA expression was further confirmed in various cultured cells, including NIH 3T3 cells, L6 myoblast cells, human umbilical vein endothelial cells, and ECV304 cells. Using F9 teratocarcinoma cell lines, which were stimulated to differentiate into the two different cell lineages of parietal and visceral endoderm, we have further examined the role of SET. The expression of set mRNA and SET protein was diminished about three-fold in both differentiated endoderm cells compared to the undifferentiated F9 cells. However, when F9 cells were subjected to serum starvation, reduction of set mRNA abundance also took place at a similar level to that observed in response to differentiation. Consistent with this, quiescent L6 myoblast showed a marked downregulation of set mRNA compared to proliferating cells. These results suggest that SET is involved mainly in the regulation of cell proliferation rather than differentiation during embryonic development.

Expression of SET is modulated as a function of cell proliferation

We explored a biological role of SET as it relates to cell proliferation and differentiation. Immunohistochemical staining demonstrated that the expression of SET was ubiquitous and diffuse over the whole embryo on gestational day 15. At a later stage of development, SET was expressed at relatively lower levels and localized to specific tissues and cells. On embryonic day 19, specific SET immunoreactivity was found in the epithelium of skin, respiratory tract, intestine, and retina as well as in muscle and cartilage. In these cells SET was stained mostly in the nucleus, which was supported indirectly by nuclear transport of enhanced green fluorescence protein-SET fusion proteins in ECV304 endothelial cells. Set mRNA expression was further confirmed in various cultured cells, including NIH 3T3 cells, L6 myoblast cells, human umbilical vein endothelial cells, and ECV304 cells. Using F9 teratocarcinoma cell lines, which were stimulated to differentiate into the two different cell lineages of parietal and visceral endoderm, we have further examined the role of SET. The expression of set mRNA and SET protein was diminished about three-fold in both differentiated endoderm cells compared to the undifferentiated F9 cells. However, when F9 cells were subjected to serum starvation, reduction of set mRNA abundance also took place at a similar level to that observed in response to differentiation. Consistent with this, quiescent L6 myoblast showed a marked downregulation of set mRNA compared to proliferating cells. These results suggest that SET is involved mainly in the regulation of cell proliferation rather than differentiation during embryonic development. J. Cell. Biochem. 74:119–126, 1999. © 1999 Wiley-Liss, Inc.

Retinoic Acid-regulated Expression of Fibroblast Growth Factor 3 Requires the Interaction between a Novel Transcription Factor and GATA-4

fgf-3 shows a complex spatial-temporal pattern of transcription during mouse development, and the gene product appears to be an important intercellular signaling molecule. Here we show that the major enhancer, which is obligatory for transcription, is composed of three elements with different properties. Both functional analyses in undifferentiated and differentiated F9 cells and characterization of DNA-protein complexes in vitro have identified the sequence motifs GTGACT(C), ATTGT, and GATA as the key transcription factor binding sites. The GTGACT(C) motif, while not essential, is required for full enhancer activity. However, binding at ATTGT is crucial for transcriptional activity and is required for cooperative binding at the proximal GATA site. The GATA binding site mediates the retinoic acid/dibutyryl cyclic AMP stimulation of transcription and correlates with the binding of Gata-4 which is induced by retinoic acid in differentiating F9 cells. The ATTGT and GATA motifs are inactive when placed separately on a minimal thymidine kinase (TK) promoter, but together they act as a strong retinoic acid-regulated enhancer. In undifferentiated F9 cells, gata-4 expression stimulates the fgf-3 promoter, whereas in differentiated F9 cells already expressing gata-4, no further increase in promoter activity was observed.

The Ras/Erk Pathway Induces Primitive Endoderm but Prevents Parietal Endoderm Differentiation of F9 Embryonal Carcinoma Cells

The formation of parietal endoderm (PE) is one of the first differentiation processes during mouse development and can be studied in vitro using F9 embryonal carcinoma (EC) cells. Treatment of F9 EC cells with retinoic acid (RA) induces differentiation toward primitive endoderm (PrE), while differentiation toward PE is induced by subsequent addition of parathyroid hormone (PTH) or PTH-related peptide (PTHrP). The signal transduction mechanisms involved in this two-step process are largely unclear. We show that the RA-induced differentiation toward PrE is accompanied by a sustained increase in Ras activity and that ectopic expression of oncogenic Ha-Ras is sufficient to induce PrE differentiation. Ras activity subsequently decreases upon PTH-induced differentiation toward PE. This is a necessary event, since expression of oncogenic Ha-Ras in PrE-like cells prevents PTH-induced PE differentiation. Expression of active PKA in PrE-like F9 cells mimics PTH-induced PE differentiation and is again prevented by oncogenic Ha-Ras. The effect of oncogenic Ras on both differentiation steps is abolished by the MEK inhibitor PD98059 and can be mimicked by constitutively active forms of Raf and MEK. In conclusion, our data suggest that activation of the Ras/Erk is sufficient to induce differentiation to PrE and to prevent subsequent differentiation toward PE. Activation of PKA down-regulates Ras activity, resulting in disappearance of this blockade and transmission of signal(s) triggering PE differentiation.

Rex-1, a gene encoding a transcription factor expressed in the early embryo, is regulated via Oct-3/4 and Oct-6 binding to an octamer site and a novel protein, Rox-1, binding to an adjacent site.

The Rex-1 (Zfp-42) gene, which encodes an acidic zinc finger protein, is expressed at high levels in embryonic stem (ES) and F9 teratocarcinoma cells. Prior analysis identified an octamer motif in the Rex-1 promoter which is required for promoter activity in undifferentiated F9 cells and is involved in retinoic acid (RA)-associated reduction in expression. We show here that the Oct-3/4 transcription factor, but not Oct-1, can either activate or repress the Rex-1 promoter, depending on the cellular environment. Rex-1 repression is enhanced by E1A. The protein domain required for Oct-3/4 activation was mapped to amino acids 1 to 35, whereas the domain required for Oct-3/4 repression was mapped to amino acids 61 to 126, suggesting that the molecular mechanisms underlying transcriptional activation and repression differ. Like Oct-3/4, Oct-6 can also lower the expression of the Rex-1 promoter via the octamer site, and the amino-terminal portion of Oct-6 mediates this repression. In addition to the octamer motif, a novel positive regulatory element, located immediately 5' of the octamer motif, was identified in the Rex-1 promoter. Mutations in this element greatly reduce Rex-1 promoter activity in F9 cells. High levels of a binding protein(s), designated Rox-1, recognize this novel DNA element in F9 cells, and this binding activity is reduced following RA treatment. Taken together, these results indicate that the Rex-1 promoter is regulated by specific octamer family members in early embryonic cells and that a novel element also contributes to Rex-1 expression.