The dual roles of geminin during trophoblast proliferation and differentiation

Geminin is a protein involved in both DNA replication and cell fate acquisition. Although it is essential for mammalian preimplantation development, its role remains unclear. In one study, ablation of the geminin gene (Gmnn) in mouse preimplantation embryos resulted in apoptosis, suggesting that geminin prevents DNA re-replication, whereas in another study it resulted in differentiation of blastomeres into trophoblast giant cells (TGCs), suggesting that geminin regulates trophoblast specification and differentiation. Other studies concluded that trophoblast differentiation into TGCs is regulated by fibroblast growth factor-4 (FGF4), and that geminin is required to maintain endocycles. Here we show that ablation of Gmnn in trophoblast stem cells (TSCs) proliferating in the presence of FGF4 closely mimics the events triggered by FGF4 deprivation: arrest of cell proliferation, formation of giant cells, excessive DNA replication in the absence of DNA damage and apoptosis, and changes in gene expression that include loss of Chk1 with up-regulation of p57 and p21. Moreover, FGF4 deprivation of TSCs reduces geminin to a basal level that is required for maintaining endocycles in TGCs. Thus, geminin acts both like a component of the FGF4 signal transduction pathway that governs trophoblast proliferation and differentiation, and geminin is required to maintain endocycles.     

The Role of heat shock protein 27 in extravillous trophoblast differentiation

Trophoblast cells from placental explants differentiate in culture to extravillous trophoblast cells (EVT cells). During trophoblast differentiation heat-shock-protein-27 (HSP27) mRNA and multidrug-resistance-protein-5 (MRP5, transporter of cyclic nucleotides) expression are increased. HSP27 is a regulator of actin filaments structure and dynamic, has a role in cell differentiation and may affect NF-kB activity. In this study we aimed to assess HSP27 level in trophoblast cells and its correlation with motility and differentiation related processes [MMPs activity, nitric oxide (NO), inducible nitric oxide synthase (iNOS), proliferation and MRP5 levels]. We evaluated HSP27 expression in a first trimester human trophoblast explants model designed to assess EVT cells differentiation/migration with/without 6-mercaptopurine (6MP, an EVT inhibitor of migration). We found that HSP27 level is expressed in the nucleous and cytoplasm of non-proliferting villous-trophoblast cells (negative for Ki67) and in the cell periphery and cytoplasm of motile EVT cells. Moreover, 6MP decreased HSP27 nucleous expression that was associated with inhibited MMP2 activity and NO production. Also decreased iNOS expression and increased MRP5 mRNA levels were observed. In conclusion, HSP27 expression is modulated in concordance with migration dependent parameters in trophoblast cells.     

Diverse subtypes and developmental origins of trophoblast giant cells in the mouse placenta

Trophoblast giant cells (TGCs) are the first terminally differentiated subtype to form in the trophoblast cell lineage in rodents. In addition to mediating implantation, they are the main endocrine cells of the placenta, producing several hormones which regulate the maternal endocrine and immune systems and promote maternal blood flow to the implantation site. Generally considered a homogeneous population, TGCs have been identified by their expression of genes encoding placental lactogen 1 or proliferin. In the present study, we have identified a number of TGC subtypes, based on morphology and molecular criteria and demonstrated a previously underappreciated diversity of TGCs. In addition to TGCs that surround the implantation site and form the interface with the maternal deciduas, we demonstrate at least three other unique TGC subtypes: spiral artery-associated TGCs, maternal blood canal-associated TGCs and a TGC within the sinusoidal spaces of the labyrinth layer of the placenta. All four TGC subtypes could be identified based on the expression patterns of four genes: Pl1, Pl2, Plf (encoded by genes of the prolactin/prolactin-like protein/placental lactogen gene locus), and Ctsq (from a placental-specific cathepsin gene locus). Each of these subtypes was detected in differentiated trophoblast stem cell cultures and can be differentially regulated; treatment with retinoic acid induces Pl1/Plf+ TGCs preferentially. Furthermore, cell lineage tracing studies indicated unique origins for different TGC subtypes, in contrast with previous suggestions that secondary TGCs all arise from Tpbpa+ ectoplacental cone precursors.     

Trophoblast giant-cell differentiation involves changes in cytoskeleton and cell motility

Trophoblast giant-cell differentiation is well-characterized at the molecular level, yet very little is known about how molecular changes affect the cellular functions of trophoblast in embryo implantation. We have found, using both explanted E7.5 mouse embryo ectoplacental cone and the rat choriocarcinoma (Rcho-1) cell line, that trophoblast differentiation is distinguished by dramatic changes in cytoarchitecture and cell behavior. Undifferentiated trophoblast cells contain little organized actin and few small, peripheral focal complexes and exhibit high membrane protrusive activity, while differentiated trophoblast giant cells contain prominent stress fibers, large internal as well as peripheral focal adhesions, and become immotile. The dramatic changes in cell behavior and cytoskeletal organization of giant cells correlate with changes in the activities of the Rho family of small GTPases and a decrease in tyrosine phosphorylation of focal adhesion kinase. Together, these data provide detailed insight into the cellular properties of trophoblast giant cells and suggest that giant-cell differentiation is characterized by a transition from a motile to a specialized epithelial phenotype. Furthermore, our data support a phagocytic erosion, rather than a migratory infiltration, mechanism for trophoblast giant-cell invasion of the uterine stroma.     

Ablation of Tpbpa-positive trophoblast precursors leads to defects in maternal spiral artery remodeling in the mouse placenta

The placenta is composed of multiple trophoblast cell types that have diverse endocrine, vascular and nutrient transport functions. We have developed a transgenic system to investigate the developmental and functional roles of specific cell types using conditional expression of a cytotoxin to induce cell ablation in transgenic mice. The Tpbpa gene is expressed in ectoplacental cone cells starting between embryonic days (E) 7.5 and 8.5, and later in the spongiotrophoblast layer of the mature placenta. Tpbpa-positive cells are progenitors of many trophoblast subtypes including three subtypes of trophoblast giant cells (TGCs) and glycogen trophoblast cells. We used a Cre recombinase transgene driven by the Tpbpa promoter to irreversibly activate a diphtheria toxin A (DTA) transgene. Cre/DTA double transgenic placentas showed dramatic reduction of Tpbpa-positive spongiotrophoblast cells by E10.5 and conceptuses died by ~ E11.5. The number of cells associated with maternal blood spaces, spiral artery TGCs (SpA-TGCs) and canal TGCs, and glycogen trophoblast cells were reduced. The loss of these specific trophoblast subtypes, especially SpA-TGCs, was correlated with a decrease in maternal spiral artery diameters, indicating a critical role of these cells in modulating the maternal vasculature. In contrast, parietal TGCs were not significantly reduced by progenitor cell ablation, suggesting that there is compensatory growth of this population and indeed a population of Ascl2 (Mash2)-positive/Tpbpa-negative cells was increased in the spongiotrophoblast layer in the Cre/DTA double transgenics. Our work demonstrates that the Tpbpa-positive lineage is essential for placental function and particularly critical for maternal vasculature remodeling.     

PAL31 expression in rat trophoblast giant cells

PAL31 is a proliferation-related acidic nuclear protein that belongs to the leucine-rich protein family and is expressed cell-cycle-dependently. Trophoblasts differentiate into the trophoblast giant cells (TGCs) through the unusual type of cell cycle, namely endoreduplication. In the present study, we investigated the spatiotemporal pattern of PAL31 expression in rat placenta and Rcho-1 cell line. The PAL31 mRNA concentration varied in different areas of the placenta, and was barely detectable in the TGC layer. In Rcho-1 cells, although the level of PAL31 mRNA decreased dramatically during differentiation, PAL31 was detected even after differentiation. The site of intranuclear localization of PAL31 mostly overlapped with that of PCNA in the undifferentiated Rcho-1 cells, while they were not overlapped in differentiated cells. Thus, the subcellular localization of PAL31 in Rcho-1 cells significantly changed, and loss of cell cycle dependency after differentiation was noted. PAL31 is suggested to play a role in the endoreduplication distinct from the usual DNA duplication.     

Actin nucleoskeleton in embryonic development and cellular differentiation

Dynamic assembly and disassembly of actin proteins play a key role in the cytoskeleton, but the cellular functions of actin are not only restricted to the cytoplasmic compartment. Recent studies have shown that actin spatiotemporally changes its polymerized state in the nucleus as well and such dynamic nature of actin is relevant to key nuclear events including gene expression, DNA damage response and chromatin organization. In this review, we highlight emerging roles of actin in the nuclear compartment especially in the context of embryonic development and cellular differentiation. We first explain how the actin nucleoskeleton can be formed and function in cells. Notably, nuclear actin dynamics are greatly altered when cell fates change, such as after fertilization and T cell differentiation. We discuss how the dynamic actin nucleoskeleton contributes to accomplishing developmental programs.     

SOCS3: an essential regulator of LIF receptor signaling in trophoblast giant cell differentiation

Suppressor of cytokine signaling 3 (SOCS3) binds cytokine receptors and thereby suppresses cytokine signaling. Deletion of SOCS3 causes an embryonic lethality that is rescued by a tetraploid rescue approach, demonstrating an essential role in placental development and a non-essential role in embryo development. Rescued SOCS3-deficient mice show a perinatal lethality with cardiac hypertrophy. SOCS3-deficient placentas have reduced spongiotrophoblasts and increased trophoblast secondary giant cells. Enforced expression of SOCS3 in a trophoblast stem cell line (Rcho-1) suppresses giant cell differentiation. Conversely, SOCS3-deficient trophoblast stem cells differentiate more readily to giant cells in culture, demonstrating that SOCS3 negatively regulates trophoblast giant cell differentiation. Leukemia inhibitory factor (LIF) promotes giant cell differentiation in vitro, and LIF receptor (LIFR) deficiency results in loss of giant cell differentiation in vivo. Finally, LIFR deficiency rescues the SOCS3-deficient placental defect and embryonic lethality. The results establish SOCS3 as an essential regulator of LIFR signaling in trophoblast differentiation.     

Chondrogenic differentiation of clonal mouse embryonic cell line ATDC5 in vitro: differentiation-dependent gene expression of parathyroid hormone (PTH)/PTH-related peptide receptor

The regulatory role of parathyroid hormone (PTH)/PTH-related peptide (PTHrP) signaling has been implicated in embryonic skeletal development. Here, we studied chondrogenic differentiation of the mouse embryonal carcinoma-derived clonal cell line ATDC5 as a model of chondrogenesis in the early stages of endochondral bone development. ATDC5 cells retain the properties of chondroprogenitor cells, and rapidly proliferate in the presence of 5% FBS. Insulin (10 micrograms/ml) induced chondrogenic differentiation of the cells in a postconfluent phase through a cellular condensation process, resulting in the formation of cartilage nodules, as evidenced by expression of type II collagen and aggrecan genes. We found that differentiated cultures of ATDC5 cells abundantly expressed the high affinity receptor for PTH (Mr approximately 80 kD; Kd = 3.9 nM; 3.2 x 10(5) sites/cell). The receptors on differentiated cells were functionally active, as evidenced by a PTH-dependent activation of adenylate cyclase. Specific binding of PTH to cells markedly increased with the formation of cartilage nodules, while undifferentiated cells failed to show specific binding of PTH. Northern blot analysis indicated that expression of the PTH/PTHrP receptor gene became detectable at the early stage of chondrogenesis of ATDC5 cells, preceding induction of aggrecan gene expression. Expression of the PTH/PTHrP receptor gene was undetectable in undifferentiated cells. The level of PTH/PTHrP receptor mRNA was markedly elevated parallel to that of type II collagen mRNA. These lines of evidence suggest that the expression of functional PTH/PTHrP receptor is associated with the onset of chondrogenesis. In addition, activation of the receptor by exogenous PTH or PTHrP significantly interfered with cellular condensation and the subsequent formation of cartilage nodules, suggesting a novel site of PTHrP action.     

PTH-1R responses to PTHrP and regulation by vitamin D in keratinocytes and adjacent fibroblasts

Vitamin D and PTHrP are essential for the differentiation of keratinocytes and epidermal development. The action of PTHrP on skin is mediated via its PTH-1R receptors present in both epidermal and dermal cells. This suggests that PTHrP may have a paracrine/autocrine role, and its receptors may act in association or in negative cooperativity. We compared the intracellular signaling pathways in response to PTHrP (1-34) and to various PTHrP peptides, the N-terminal (1-34), Mid region (67-89), and C-terminal (107-139) fragments, and the possible modulation of PTHrP and its receptor mRNA expressions by vitamin D. Adjacent dermal fibroblasts as freshly isolated keratinocytes expressed both PTHrP and PTH-1R mRNAs, and responded to the various PTHrP fragments. bPTH and PTHrP(1-34) increased both cellular cAMP and [Ca(2+)]i in keratinocytes and fibroblasts. In contrast, PTHrP (107-139) increased [Ca(2+)]i but not cAMP in the two cell types. PTHrP (67-89) had no effect in keratinocytes, and only increased [Ca(2+)]i in fibroblasts. Vitamin D deficiency in weaned rats increased the expression of PTHrP mRNA in keratinocytes, and decreased it in fibroblasts and kidneys. Vitamin D deficiency increased PTH-1R mRNA expression in keratinocytes and kidneys, but not in fibroblasts. Although keratinocytes and skin fibroblasts are target cells for PTHrP and express PTH-1R, the two adjacent cell types differ as regards their intracellular signaling in response to PTHrP peptides. Moreover vitamin D regulates PTHrP and PTH-1R in a cell-specific manner.     

Expression and function of PPARgamma in rat placental development

Peroxisome proliferator-activated receptor (PPAR) gamma is a nuclear receptor known to regulate adipogenesis. Deletion of the PPARgamma gene in the mouse results in death by embryonic day 10.0 (E10.0) due to the failure of establishment of a labyrinth layer in the placenta, which suggests that PPARgamma is involved in trophoblast differentiation. To define PPARgamma function further in placental development, the expression and localization of the PPARgamma gene in the rat placenta was investigated. RT-PCR analysis shows the presence of PPARgamma mRNA in the placenta of day 11 of pregnancy (d11). The expression level is higher at d13 and then later decreased. Immunohistochemistry detects both PPARgamma and its putative intrinsic ligand, 15-deoxy-Delta(12,14)-prostaglandin J(2), in the trophoblast of layer I which lined the maternal sinus. Oral administration of troglitazone, an agonist of PPARgamma, to pregnant rats between d9 and d11 increases the expression level of PPARgamma in the placenta and reduces the mortality of the fetuses by half. These results suggest that PPARgamma is required not only for trophoblast differentiation but also trophoblast maturation to establish maternal-fetal transport.     

Parathyroid hormone-related protein reduces alveolar epithelial cell proliferation during lung injury in rats

Parathyroid hormone-related protein (PTHrP) is a growth inhibitor for alveolar type II cells and could be a regulatory factor for alveolar epithelial cell proliferation after lung injury. We investigated lung PTHrP expression in rats exposed to 85% oxygen. Lung levels of PTHrP were significantly decreased between 4 and 8 days of hyperoxia, concurrent with increased expression of proliferating cell nuclear antigen and increased incorporation of 5-bromo-2'-deoxyuridine (BrdU) into DNA in lung corner cells. PTHrP receptor was present in both normal and hyperoxic lung. To test whether the fall in PTHrP was related to cell proliferation, we instilled PTHrP into lungs on the fourth day of hyperoxia. Eight hours later, BrdU labeling in alveolar corner cells was 3.2 +/- 0.4 cells/high-power field in hyperoxic PBS-instilled rats compared with 0.5 +/- 0.3 cells/high-power field in PTHrP-instilled rats (P < 0. 01). Thus PTHrP expression changes in response to lung injury due to 85% oxygen and may regulate cell proliferation.     

Hypoxia impairs cell fusion and differentiation process in human cytotrophoblast,in vitro

During human pregnancy, the trophoblast develops from differentiation of cytotrophoblast cells into an endocrine active syncytiotrophoblast. In culture, isolated mononuclear cytotrophoblasts aggregate and then fuse to form a syncytium, reproducing the in vivo process. In this study, we examined the effect of low oxygen tension (approximately 9%, hypoxia) compared to standard conditions (approximately 19% oxygen, normoxia) on these cellular events. Under hypoxia, syncytial formation was less frequently observed, cell staining and electron microscopy revealed that cytotrophoblasts remain aggregated, with a positive proliferative cell nuclear antigen (PCNA) immunostaining. Desmoplakin and E-cadherin, both known to disappear with cytotrophoblast fusion, showed persistent expression in hypoxic cells after 3 days of culture. In contrast, the expression of actin and ezrin, two cytoskeletal proteins, was unchanged. hCG secretion and hPL expression were both decreased in hypoxic cells, reflecting a reduced syncytial formation. Thus, on day 3, the mean values for hCG secretion were 1,100 ± 155 and 289 ± 26 mlU/mL in normoxic and hypoxic conditions, respectively. The reduced cell fusion process as well as hCG secretion and hPL expression under hypoxia were reversed by reoxygenation of the cells. We conclude that under hypoxia, the formation of functional syncytiotrophoblast is impaired due to a defect in the cytotrophoblast fusion process. This may explain the observation of a higher number of cytotrophoblast cells and a reduced syncytial layer in placentas of some pathological pregnancies. © 1996 Wiley-Liss, Inc.