André Malassiné

Characterization of Human Villous and Extravillous Trophoblasts Isolated from First Trimester Placenta

Trophoblasts of the human placenta differentiate along two pathways to give either extravillous cytotrophoblasts (EVCT) with invasive properties and that are implicated in the implantation process, or villous cytotrophoblasts (VCT) that by cell fusion form multinucleated syncytiotrophoblasts. We report the first isolation and purification of these two cell types from the same chorionic villi of first trimester human placenta. We also studied their differentiation in vitro. Electron microscopy showed that in contrast to VCT, EVCT had no microvilli but contained large fibrinoid inclusions. EVCT cultures required a matrix to invade, and as previously established, VCT cultured on plastic dishes aggregated and fused to form syncytiotrophoblasts. These differentiation processes were characterized by a particular pattern of gene expression as assessed by real-time PCR and confirmed by immunocytochemical analysis of the corresponding proteins. EVCT cultured in vitro expressed high levels of HLA-G, c-erbB2, human placental lactogen, and very little human chorionic gonadotropin. Interestingly, TGFβ2 was a marker of EVCT in vitro and in situ. These data offer a new tool for cell biologists to study the molecular mechanisms involved in human placental development and its pathology.

Involvement of connexin 43 in human trophoblast cell fusion and differentiation.

The syncytiotrophoblast is the principal component of the human placenta involved in feto-maternal exchanges and hormone secretion. The syncytiotrophoblast arises from the fusion of villous cytotrophoblasts. We recently showed that functional gap junctional intercellular communication (GJIC) is an important prerequisite for syncytiotrophoblast formation and that connexin 43 (Cx43) is present in cytotrophoblasts and in the syncytiotrophoblast. To determine whether Cx43 is directly involved in trophoblast fusion, we used an antisense strategy in primary cultures of human villous cytotrophoblasts that spontaneously differentiate into the syncytiotrophoblast by cell fusion. We assessed the morphological and functional differentiation of trophoblasts by desmoplakin immunostaining, by quantifying hCG (human chorionic gonadotropin) production and by measuring the expression of specific trophoblast genes (hCG and HERV-W). Furthermore, we used the gap-FRAP (fluorescence recovery after photobleaching) method to investigate functional GJIC. Cytotrophoblasts treated with Cx43 antisense aggregated and fused poorly. Furthermore, less HERV-W env mRNA, hCGβ mRNA and hCG secretion were detected in Cx43 antisense-treated cytotrophoblasts than in cells treated with scrambled antisense. Treatment with Cx43 antisense dramatically reduced the percentage of coupled trophoblast cells. Taken together, these results suggest that Cx43 is directly involved in human trophoblast cell-cell communication, fusion and differentiation.

Hormones and human trophoblast differentiation

In the human, fetal cytotrophoblastic cells play a key role in the implantation process and in placental development. With the progression of placentation, two pathways of differentiation lead to the formation of two distinct phenotypes. In the villous trophoblast (fusion phenotype), the trophblast differentiates from the fusion of mononuclear cytotrophoblastic cells into a syncytium, the syncytiotrophoblast. Bathing the maternal blood, the syncytiotrophoblast is involved in maternal-fetal exchanges and in placental endocrine functions. In the extravillous trophoblast (proliferative/invasive phenotype), the cytotrophoblastic cells proliferate and migrate into the decidua, remodeling the pregnant endometrium and its vasculature. This review summarizes our current knowledge of the key step of villous differentiation—the cell-cell fusion of the cytotrophoblastic cells—and on the invasion process of extravillous trophoblast. Experimental evidence demonstrates that the genetic differentiation/invasion programs of cytotrophoblastic cells could be modulated by their environment: oxygen, extracellular matrix, and soluble factors (cytokines, growth factors, and hormones). Cytotrophoblastic cells fusion and the functional differentiation of villous trophoblast are specifically stimulated by estradiol, glucocorticoids, and human chorionic gonadotropin (hCG) whereas progesterone is ineffective. Because these hormones are temporally secreted in large amounts and present at the fetomaternal interface, they are in good position to play a physiologic role in trophoblast differentiation. hCG may be important very early in pregnancy, when production of this glycoprotein is maximal, whereas estrogen increasingly produced by the fetoplacental unit and cortisol secreted from the fetal adrenal may be implicated in the end-stage maturation and aging of the trophoblast.

Human placenta as an endocrine organ

The placenta is a unique, autonomous and transient organ. It ensures maternal-fetal exchanges and is also involved in maternal tolerance of feto-paternal antigens. The human placenta is characterized by the major invasion of the trophoblast, which comes in contact with the maternal blood, and by the intensity and the specificity of its endocrine functions. Placental hormones are required for the establishment and maintenance of pregnancy, adaptation of the maternal organism to pregnancy, fetal growth and well being, and development of the mechanisms involved in parturition. The endocrine tissue of the placenta is the syncytiotrophoblast, which covers the chorionic villi, and arises from the fusion of the cytotrophoblasts. In this review we will summarize the particulars of human syncytiotrophoblast development and endocrine functions.

Requirement of Gap Junctional Intercellular Communication for Human Villous Trophoblast Differentiation

Abstract During pregnancy, the villous trophoblast develops from the fusion of cytotrophoblastic cells (CT) into a syncytiotrophoblast (ST), supporting the main physiological functions of the human placenta. Connexin43 (Cx43) is demonstrated in situ and in vitro in the villous trophoblast between CT and between CT and ST. Moreover, the presence of a gap junctional intercellular communication (GJIC) during in vitro trophoblast differentiation was previously demonstrated. Because the exchange of molecules through gap junctions is considered to play a major role in the control of cell and tissue differentiation, we studied the effects of a gap junctional uncoupler, heptanol, on morphological and functional trophoblast differentiation and on GJIC measured by the fluorescence recovery after photobleaching method. We found that when the GJIC was interrupted, CT still aggregated but fused poorly. This morphological effect was associated with a significant decrease of trophoblastic-specific gene expression (β human chorionic gonadotropin and human chorionic somatomammotropin). This blocking action was reversible as demonstrated by recovery of GJIC and trophoblast differentiation process after heptanol removal. Moreover, the inhibition of the trophoblast differentiation did not affect Cx43 transcript expression and Cx43 protein expression. These data suggest that the molecular exchanges through gap junctions preceding cellular fusion are essential for trophoblast differentiation generating the multifunctional syncytiotrophoblast.

ZO-1 is involved in trophoblastic cell differentiation in human placenta

Trophoblastic cell-cell fusion is an essential event required during human placental development. Several membrane proteins have been described to be directly involved in this process, including connexin 43 (Cx43), syncytin 1 (Herv-W env), and syncytin 2 (Herv-FRD env glycoprotein). Recently, zona occludens (ZO) proteins (peripheral membrane proteins associated with tight junctions, adherens junctions, and gap junctions) were shown to be involved in mouse placental development. Moreover, zona occludens 1 (ZO-1) was localized mainly at the intercellular boundaries between human trophoblastic cells. Therefore the role of ZO-1 in the dynamic process of human trophoblastic cell-cell fusion was investigated using primary trophoblastic cells in culture. In vitro as in situ, ZO-1 was localized mainly at the intercellular boundaries between trophoblastic cells where its expression substantially decreased during differentiation and during fusion. At the same time, Cx43 was localized at the interface of trophoblastic cells and its expression increased during differentiation. To determine a functional role for ZO-1 during trophoblast differentiation, small interfering RNA (siRNA) was used to knock down ZO-1 expression. Cytotrophoblasts treated with ZO-1 siRNA fused poorly, but interestingly, decreased Cx43 expression without altering the functionality of trophoblastic cell-cell communication as measured by relative permeability time constant determined using gap-FRAP experiments. Because kinetics of Cx43 and ZO-1 proteins show a mirror image, a potential association of these two proteins was investigated. By using coimmunoprecipitation experiments, a physical interaction between ZO-1 and Cx43 was demonstrated. These results demonstrate that a decrease in ZO-1 expression reduces human trophoblast cell-cell fusion and differentiation.

Human endogenous retrovirus-FRD envelope protein (syncytin 2) expression in normal and trisomy 21-affected placenta

Human trophoblast expresses two fusogenic retroviral envelope proteins, the widely studied syncytin 1, encoded by HERV-W and the recently characterized syncytin 2 encoded by HERV-FRD. Here we studied syncytin 2 in normal and Trisomy 21-affected placenta associated with abnormal trophoblast differentiation. Syncytin 2 immunolocalization was restricted throughout normal pregnancy to some villous cytotrophoblastic cells (CT). During the second trimester of pregnancy, syncytin 2 was immunolocalized in some cuboidal CT in T21 placentas, whereas in normal placentas it was observed in flat CT, extending into their cytoplasmic processes. In vitro, CT isolated from normal placenta fuse and differentiate into syncytiotrophoblast. At the same time, syncytin 2 transcript levels decreased significantly with syncytiotrophoblast formation. In contrast, CT isolated from T21-affected placentas fused and differentiated poorly and no variation in syncytin 2 transcript levels was observed. Syncytin 2 expression illustrates the abnormal trophoblast differentiation observed in placenta of fetal T21-affected pregnancies.

Dominant negative effect of connexin33 on gap junctional communication is mediated by connexin43 sequestration

Gap junctional intercellular communication is involved in the control of cell proliferation and differentiation. Connexin33, a member of the multi-gene family of gap junction proteins, exerts an inhibitory effect on intercellular communication when injected into Xenopus oocytes. However, the molecular mechanisms involved remain to be elucidated. Our results show that connexin33 was only expressed within the seminiferous tubules in the testis. In contrast to the majority of connexins, connexin33 was unphosphorylated. Immunoprecipitation experiments revealed that connexin33 physically interacted with connexin43, mainly with the phosphorylated P1 isoform of connexin43 but not with connexin26 and connexin32, two other connexins expressed in the tubular compartment. In Sertoli cells and COS-7 cells, connexin43 was located at the plasma membrane, whereas in connexin33 transfected cells, the specific association of connexin33/43 was sequestered in the intracellular compartment. High-resolution fluorescent deconvolution microscopy indicated that the connexin33/43 complex was mainly found within early endosomes. Sequestration of connexin33/43 complex was associated with a complete inhibition of the gap junctional coupling between adjacent cells. These findings provide the first evidence of a new mechanistic model by which a native connexin, exerting a dominant negative effect, can inhibit gap junctional intercellular communication. In the testis, connexin33 could exert a specific role on germ cell proliferation by suppressing the regulatory effect of connexin43.

High density lipoprotein interaction with human placenta: Biochemical and ultrastructural characterization of binding to microvillous receptor and lack of internalization

Specific receptor and internalization process for low density lipoprotein (LDL) and modified LDL (acetyl-LDL) have been well characterized in placental microvilli and in trophoblastic cells in culture. The aim of this study was to investigate high density lipoprotein (HDL3) binding and its eventual subsequent internalization in both these purified placental preparations. Isolated term placental microvilli were used for binding of [125I]HDL3 (devoid of apoprotein E). HDL3 were conjugated to colloidal gold for ultrastructural visualization of binding and internalization in syncytiotrophoblast in culture. Saturable binding of HDL3 was identified. Scatchard analysis revealed a Kd value of 24.2 +/- 8.0 micrograms HDL3 protein/ml and a maximum binding capacity at 4 degrees C of 128.2 +/- 54.5 micrograms HDL3 protein/mg of membrane protein. These sites have broad specificity: both LDL and acetyl-LDL were able to partially inhibit the HDL3 binding. Ultrastructural study confirms that gold-HDL3 bind specifically to syncytiotrophoblast membrane. However, after incubation at 37 degrees C, an internalization process similar to those described for gold-LDL and gold-acetyl-LDL was not observed for gold-HDL3. These results demonstrate specific HDL3 binding without internalization. The physiological significance of an HDL3 membranous interaction and the placental steroidogenesis remains to be established.

Endothelin-1 binding sites and immunoreactivity in the cultured human placental trophoblast: evidence for an autocrine and paracrine role for endothelin-1.

In human placenta, endothelin (ET) could derive from maternal, fetal, and/or endogenous sources. Therefore, localization of ET-1 was investigated by immunohistochemistry in human term placenta and in cultured trophoblasts. In sections of placenta, ET-1 immunoreactivity (ET-1 IR) was specifically detected in the endothelium of the vessels and in the syncytiotrophoblasts of the villi. ET-1 IR was also detected in the decidual cells and in the extravillous cytotrophoblasts of the basal plate. The extravillous cytotrophoblasts of the chorionic plate and of the placental septa also exhibited strong ET-1 IR. For trophoblast culture, cytotrophoblastic cells were obtained from placental villi by trypsin-DNAse dispersion, further purified on a Percoll gradient, and enriched by employing a monoclonal anti-HLA class I antibody. After different periods of culture of purified cytotrophoblastic cells (1-5 days), ET-1 IR was observed in 95% of cells: cytotrophoblastic cells, trophoblast aggregates, and syncytiotrophoblasts. The presence of ET-1,2 immunoreactivity (ET-1,2 IR) in the culture media was demonstrated by radioimmunoassay. A uniform daily production of the peptide was observed over at least 5 days (approximately 50 fmol/10(6) cells/24 h). Furthermore, trophoblastic cells that had been cultured for 5 days contained significant amounts of ET-1,2 IR (24 fmol/10(6) cells). These results suggest a trophoblastic origin for ET-1 and support the hypothesis of a paracrine and autocrine action of the peptide in the physiology of the trophoblast and placenta.