The use of laser capture microdissection (LCM) and quantitative polymerase chain reaction to define thyroid hormone receptor expression in human 'term' placenta

Term 'villous' placenta consists of a heterogeneous mix of different cell types comprising the trophoblast layers, villous stroma and fetal blood vessels. The importance of using techniques which allow investigation of pure populations of cells has been increasingly recognised. We demonstrate the use of laser capture microdissection (LCM) in combination with quantitative RT-PCR (QPCR) to assess the relative expression of mRNAs encoding the major thyroid hormone receptor (TR) isoforms (alpha1, alpha2 and beta1) in trophoblasts (syncytiotrophoblast and cytotrophoblast layers) compared with stromal cells in human term placenta. Highly reproducible results for each gene were obtained for each placental sample studied (n = 6). There was significantly less mRNA encoding TRalpha1 (68%; p = 0.05) and TRbeta1 (40%; p = 0.03) in the trophoblast layer compared to the heterogeneous stromal cells. However, there was no significant difference in TRalpha2 mRNA expression between the two groups of cells. CONCLUSION: LCM with QPCR can precisely locate and accurately quantify mRNA expression in specific cell populations from placental tissue.     

Expression,Regulation and Functional Characterization of Matrix Metalloproteinase-3 of Human Trophoblast

MMP-3 has been detected in human placenta and reduced expression of the enzyme was observed in invasive trophoblasts of patients with severe preeclampsia. However, detailed expression pattern, regulation and biological properties of the placental protease have not been elucidated so far. RT-PCR analyses, Western blotting and enzyme activity assays revealed that pro- and active form of MMP-3 were predominantly expressed in purified first trimester villous trophoblasts, in invasive cytotrophoblasts of differentiating explant cultures and in trophoblastic SGHPL-4 cells. Accordingly, immunofluorescene of first trimester placental tissues detected MMP-3 mainly in villous and extravillous cytotrophoblasts. IL-1β, an inducer of MMP-3 in decidual cells, increased secretion and activity of the protease in trophoblast supernatants in a dose- and time-dependent manner. IL-1β-stimulated production of the enzyme was suppressed in the presence of inhibitors of MAPK and AKT signalling. Similar to recombinant MMP-3, MMP-3 in supernatants of IL-1β-stimulated decidual stromal or SGHPL-4 cells degraded IGFBP-1 in vitro resulting in the appearance of cleavage products at approximately 25, 22, 17, 14 and 11 kD. However, cleavage assays using recombinant MMP-2 suggested that the gelatinase may contribute to IGFBP-1 degradation in trophoblast supernatants. Despite its effects on MMP-3 expression IL-1β failed to significantly alter invasion of SGHPL-4 cells through Matrigel-coated transwells. In conclusion, the data suggest that invasive trophoblast cell models secrete bioactive MMP-3. Inducible expression of the protease involves MAPK and AKT signalling. In addition to the decidua, MMP-3 of trophoblasts may contribute to the regulation of the IGF system by degrading IGFBP-1.     

Studies of Mesenchymal Cells from 1st Trimester Human Placenta: Expression of Cytokeratin Outside the Trophoblast Lineage

A fibroblast cell strain that expressed cytokeratins 8 and 18 was isolated from explanted first trimester placenta. Its properties were consistent with an origin in the villous fibroblast-myofibroblast lineage, including expression of vimentin, smooth muscle alpha-actin and fibroblast surface protein. The cells grew rapidly in vitro, and exhibited tightly aligned bipolar morphology at confluence, absence of multi-nucleated cells, lack of secreted chorionic gonadotrophin, and absence of HLA G, placental alkaline phosphatase and pregnancy-specific beta-1 glycoprotein (SP1). On these criteria it was concluded they were not trophoblasts. On the basis of their morphology, cytokeratin expression and absence of CD34 and endoglin it was concluded they were not endothelial cells. They lacked desmin and smooth muscle myosin and so were not vascular smooth muscle cells. Further mesenchymal cell isolates were studied to determine the generality of these findings. Phenotypic heterogeneity was a consistent characteristic, but cytokeratin-positive cells were always present both in first trimester and term strains. Desmin was absent from almost all the cells isolated using the protocols employed, despite its occurrence in a significant subpopulation of cells in the villous stroma. Cytokeratins 8 and 18 can be observed in the stromal compartment of both first trimester and term placental villi. Cytokeratin has hitherto been regarded as a highly reliable marker for cells of the trophoblast lineage in vitro. These observations suggest that care should be taken in characterization of placental cell isolates; trophoblasts should be identified by the presence of cytokeratin 7 in preference to cytokeratin 8/18. The functional significance of cytokeratin expression in placental mesenchymal cells remains to be established.     

Differential expression of placental villous angiopoietin-1 and -2 during early, mid and late baboon pregnancy

Although vascular endothelial growth factor (VEGF), angiopoietin-1 (Ang-1) and Ang-2 have important roles in angiogenesis, very little is known about the regulation of these factors in the villous placenta during human pregnancy. In the present study, to investigate whether placental expression of Ang-1, Ang-2 and VEGF was altered in a cell-specific manner with advancing baboon gestation, the mRNA levels of these growth factors were determined by RT-PCR in cells isolated by Percoll gradient centrifugation from and protein localization assessed by immunocytochemistry in the villous placenta at early (day 60), mid (day 100) and late (day 170, term is 184 days) baboon gestation. Mean (+/-SE) Ang-1 mRNA levels, relative to 18S rRNA, in villous syncytiotrophoblast (3.92+/-0.68) and cytotrophoblast (1.31+/-0.31) cell fractions were highest on day 60 of gestation, then decreased by approximately 2.5-fold (P<0.05) to 1.39+/-0.29 and 0.49+/-0.07, respectively, on day 170. Moreover, Ang-1 mRNA levels in the villous stromal cells and Ang-2 mRNA levels in all placental villous cell fractions were similar on days 60, 100, and 170 of gestation. In contrast to Ang-1 and Ang-2, placental villous cytotrophoblast VEGF mRNA levels were increased 2.94-fold (P<0.05) between mid (0.67+/-0.15) and late (1.97+/-0.49) gestation. A corresponding decrease in Ang-1, absence of change in Ang-2, and increase in VEGF protein immunocytochemical expression were exhibited in placental trophoblast with advancing baboon pregnancy. Ang-1/Ang-2 and the angiopoietin Tie-2 receptor were expressed in vascular endothelial cells of the villous placenta, indicating that these blood vessel cells are a major site of ligand-receptor interaction for angiogenesis during primate pregnancy. We conclude that there is a cell-specific differential change in placental villous trophoblast expression of VEGF, Ang-1, and Ang-2 which we propose is important in regulating angiogenesis in the villous placenta during primate pregnancy.     

Does plasminogen activator inhibitor-1 (PAI-1) control trophoblast invasion? A study of fetal and maternal tissue in intrauterine, tubal and molar pregnancies

Urokinase plasminogen activator, its receptor and the inhibitor PAI-1 are believed to control proteolysis and remodelling of maternal tissue during trophoblast invasion. This system appears to be strictly regulated in normal intrauterine pregnancies whereas tubal and molar pregnancies seem to be characterized by an uncontrolled excessive placental invasion. This study evaluates subcellular PAI-1 by immunohistochemistry in the villous placenta, in the basal plate and placental bed, and in the decidual compartments of normal, tubal and molar pregnancies. PAI-1 was present in villous syncytiotrophoblasts and co-localized focally with fibrin-type fibrinoid on the surface of the chorionic villi. Basal plate and placental bed extravillous interstitial trophoblasts, as well as vascular trophoblasts, were also PAI-1 positive. In the decidua parietalis, PAI-1 was observed in the cytoplasm of the non-invaded decidual cells. In the decidua basalis comprising the basal plate, PAI-1 was seen to be membrane-associated or confined to the extracellular matrix (ECM) facing the invasive front of anchoring villi. The ECM of decidua capsularis and chorion laeve displayed the most pronounced PAI-1 expression towards the maternal interface. In contrast, the majority of placental bed decidual cells adjacent to the interstitial and vascular trophoblasts were PAI-1 negative. Only a few stromal cells distant from the implantation site were PAI-1 positive in the tubal pregnancies and decidualization was not present. Likewise, excessive decidual necrosis and fibrinoid deposition devoid of PAI-1 was a common finding in complete molar pregnancies. These results suggest that PAI-1 defines specific extravillous invasive trophoblasts within the maternal decidua. Moreover, maternal cellular lack of PAI-1 in tubal pregnancies and excessive decidual necrosis in molar pregnancies indicate an uncontrolled placental invasion. The present data indicate that trophoblast invasion is primarily regulated by signals from decidual cells.     

Localization and Significance of Urokinase Plasminogen Activator and its Receptor in Placental Tissue from Intrauterine, Ectopic and Molar Pregnancies

Urokinase plasminogen activator receptor (uPAR) is a membrane-anchored protein with urokinase plasminogen activator (uPA) as the ligand. This complex induces proteolysis and remodelling of maternal decidua during placental implantation. The presence of uPAR on trophoblasts is supposed to promote adhesion, migration and invasion. In cancer tissue, high levels of uPAR are correlated with a poor prognosis. This immunohistochemical study shows the localization of uPA and uPAR in a prospective design with stereological sampling of fetal and maternal tissue from normal, ectopic and hydatidiform molar (HM) pregnancies. Cytokeratin and Ki67 were used as markers for trophoblasts and proliferating cells. Membrane-bound uPAR was observed on villous non-proliferating intermediate trophoblasts (IT) within cell columns in intrauterine and ectopic pregnancies. The corresponding proliferating IT with cytological atypia sprouting from the chorionic villi in HM was uPAR-negative. uPA but not uPAR was observed in anchoring distal IT at the attachment-point to the basal plate. In the placental bed, extravillous interstitial trophoblasts were uPA-positive but uPAR-negative. The trophoblast giant cells were both uPA- and uPAR-negative. In relation to the maternal vessels, a focal distribution for uPA and uPAR was present in the endovascular and perivascular trophoblasts. The intraluminal trophoblasts overlying endothelial cells were uPAR-positive only. In maternal tissue from intrauterine and molar pregnancies, uPAR was seen in the decidual cells in a zone facing the anchoring villi and the fibrinoid lesions with embedded trophoblasts. In contrast, the stromal cells of the fallopian tube without a decidual reaction facing the implanted gestation were uPAR-negative. Non-invaded decidual, myometrial and muscular tissue of the pregnant uterus and fallopian tube was extensively positive for uPA whereas 'pseudodecidual' cells from the intrauterine evacuate in patients with an ectopic pregnancy only showed a focal and scanty reaction for uPA. When trophoblast invasion of the decidua was present, the decidual cells were uPA-negative. A semi-quantitative assessment of the receptor was estimated in villous IT within cell columns in normal and molar pregnancies but, in conclusion, quantitative evaluation of uPAR cannot be used to predict development of post-molar persistent trophoblastic disease (PTD).     

Pre-eclampsia does not change the adhesion molecule status in the placental bed

During normal placentation trophoblast cells invade maternal tissues and remodel the uterine arteries into low-resistance channels. In pre-eclampsia, trophoblast invasion is impaired and this, along with endothelial dysfunction, has been suggested to play a role in the pathogenesis of pre-eclampsia. We studied the expression of adhesion molecules important for leukocyte extravasation in the placental bed with immunohistochemistry and compared the expression in pre-eclampsia to that in normal pregnancy. Our major finding was that only invasive trophoblasts expressed cutaneous lymphocyte antigen-1 (CLA-1) in the third trimester of pregnancy, whereas villous trophoblasts did not. In the first trimester both villous trophoblasts and invasive trophoblast cells in decidua remained negative for CLA-1. Pre-eclampsia did not change the expression of leukocyte-endothelium adhesion or lymphocyte homing-associated antigens, ICAM-1, ICAM-2, VCAM, P-selectin, E-selectin, L-selectin, CLA-1, CD73, VAP-1 and alphaEbeta7 in the placental bed. Furthermore, pre-eclampsia was not associated with an aberrant accumulation of lymphocytes carrying antigens of any particular known organ-specific homing systems. The results on the unchanged pattern of adhesion molecule expression in pre-eclampsia suggests that there is no major change in the adhesive properties of the endothelium of the placental bed in pre-eclampsia.     

Reactivity of two monoclonal antibodies (Troma 1 and CAM 5.2) on tissue sections--as a histological trophoblast marker in normal pregnancy and trophoblastic disease

In normal and molar pregnancy, non-villous trophoblasts which exist in the placental bed are thought to be difficult to be distinguished morphologically from the surrounding maternal cells. We examined the reactivities of two monoclonal antibodies (Troma 1 and CAM 5.2) by an immunoperoxidase technique and analyzed their usefulness as histological trophoblast markers. Materials were taken from 41 uteri of normal pregnancy, 7 uteri of hydatidiform mole, 2 uterine gestational choriocarcinoma, 1 tubal tissue of non-gestational choriocarcinoma and 5 non-gestational uteri. The reactivity of Troma 1 was observed on frozen sections and paraffin sections were employed in the analysis of CAM 5.2. The reactivities of these antibodies were the same. In nongestational tissue, they reacted with endometrial gland epithelia and endometrial covering epithelia. In placental bed of normal pregnancy, they reacted with villous and non-villous trophoblasts, besides endometrial gland epithelia. In molar sections, they reacted with gland epithelia, villous trophoblasts and also non-villous trophoblasts which proliferated towards maternal tissue. In choriocarcinoma, they reacted with carcinoma cells specifically. Since endometrial gland epithelia are easily identified histologically, it was concluded that these antibodies could work as histological trophoblast markers in normal pregnancy and trophoblastic disease.     

Morphological and immunohistochemical study on specimens of trophoblastic diseases in which the presence of a villous formation could not be established

The histopathological discrimination between malignant trophoblastic diseases and benign trophoblastic diseases depends on the presence or absence of a villous structure. However, molar extravillous trophoblasts and cells in some placental site trophoblastic tumors (PSTT) of a benign nature, lack a villous structure. We therefore observed the morphology of trophoblastic cells which do not constitute a villous structure, including choriocarcinoma cells, and analyzed the location of placental proteins in these cells immunohistochemically. The results were as follows: 1. Molar extravillous trophoblasts were composed of large mononuclear cells and multinuclear cells. Most of them were positive for hPL and negative for hCG and SP1. 2. Choriocarcinoma consisted of cytotrophoblast-like cells, syncytiotrophoblast-like cells, large mononuclear cells and multinuclear cells resembling large mononuclear cells. HCG was noted in syncytiotrophoblast-like cells and large mononuclear cells, while hPL and SP1 were found only in syncytiotrophoblast-like cells. 3. PSTT was made up of large mononuclear cells and multinuclear cells which contained abundant hPL and very little hCG and SP1 or none at all. Molar extravillous trophoblasts were clearly distinguishable from choriocarcinoma cells in terms of their morphology and the location of placental proteins. In contrast, it seemed difficult to distinguish cells of PSTT from molar extravillous trophoblasts on a cell level.     

A Placental Protective Role for Trophoblast-Derived TNF-Related Apoptosis-Inducing Ligand (TRAIL)

Recent studies show that apoptosis, programmed cell death, plays an important role in the normal development of the human placenta and that an altered balance between proliferation and apoptosis of villous trophoblasts is associated with abnormal pregnancies. The TNF-related apoptosis-inducing ligand (TRAIL) is a molecule belonging to TNF superfamily. The role of TRAIL and its Death Receptor 5 (DR5) in regulating villous trophoblast cell turnover in normal and pathologic pregnancies remains to be explored. In order to elucidate the role of TRAIL in the regulation of placental growth, primary cytotrophoblast cells were isolated from normal term placentas (n = 13) and cultured for 18 and 66 h to generate mononucleate and multinucleate trophoblasts, respectively. The protein expression and localisation of TRAIL and DR5 were determined by Western blotting and immunofluorescence. Secreted sTRAIL was also measured by ELISA. Trophoblast apoptosis was measured by TUNEL in the presence of recombinant TRAIL (rTRAIL), and DR5 relocalisation was assessed by immunostaining after 18 h exposure to TNFα. We demonstrated that TRAIL protein expression and the secretion of soluble TRAIL (sTRAIL) were down-regulated in syncytialised villous trophoblasts and that sTRAIL was independent of biochemical differentiation, as TRAIL-neutralizing antibody (2E5) failed to influence hCG production. TRAIL immunoreactivity was detected in mono- and multinucleated trophoblast cells and localised to the cytoplasm and cellular membranes – more intense staining was associated with apoptotic nuclei. rTRAIL failed to induce apoptosis in trophoblasts cells owing to the nuclear localisation of DR5. However, TNFα treatment caused the redistribution of intracellular DR5 to the cell surface, potentiating apoptotic susceptibly to exogenously administered rTRAIL. These findings highlight a mechanism by which TRAIL and DR5 serve to protective trophoblasts in normal development, but may be activated in conditions of excessive TNFα.     

TNF-alpha/TNFRI in primary and immortalized first trimester cytotrophoblasts

During the first trimester of pregnancy endogenous expression of tumour necrosis factor (TNF)-alpha has been detected in villous, as well as in proliferating and invading extravillous, trophoblasts suggesting that the protein could be involved in trophoblast differentiation. To gain insights into the putative role of the TNF-alpha signalling pathway, we investigated expression of its receptors, TNFR I and II, in first trimester placentae and early trophoblasts, and studied the influence of the cytokine on cell proliferation and apoptosis. ELISA and RT-PCR revealed secretion/expression of TNFRI protein/mRNA in immortalized ED27 cells and purified first trimester cytotrophoblasts, while soluble TNFRII was undetectable in cell culture supernatants. In agreement, immunohistochemical analyses of first trimester placentae showed that TNFRI is localized to the villous cyto- and syncytiotrophoblast, to the proliferating cytotrophoblasts of the cell islands and cell columns, as well as to extravillous cells invading decidual tissue. TNFRII, however, was absent in early trophoblast populations. Interleukin (IL)-1 and phorbol 12-myristate 13-acetate (PMA) induced shedding of TNFRI from ED27 and primary cells suggesting that under inflammatory conditions the soluble receptor protein may protect from cytotoxic effects of TNF-alpha. Upon incubation with increasing amounts of TNF-alpha no significant changes in DNA-content or cell numbers were found, suggesting that the cytokine does not augment proliferation of primary cytotrophoblasts. High doses of TNF-alpha, however, provoked growth arrest in ED27 cells as evaluated by cell counting, but did not induce necrosis/apoptosis as was assessed by TUNEL assay. In first trimester cells addition of elevated amounts of TNF-alpha resulted in the appearance of TUNEL-positive cells and an increase in caspase-3 enzyme activity suggesting that the TNF-alpha-dependent apoptotic cascade is executed in a portion of the early cytotrophoblasts.     

Immunohistochemical localization of hCG alpha, hCG beta CTP, hPL and SP1 on villous and extravillous trophoblasts in normal human pregnancy

Trophoblasts are divided into villous trophoblasts and extravillous trophoblasts, depending on whether they constitute a villous structure, and cell columns intervene between them. We conducted an immunohistochemical localization of human chorionic gonadotropin (hCG) alpha, hCG beta C-terminal peptide (CTP), human placental lactogen (hPL) and pregnancy-specific beta 1-glycoprotein (SP1) on the trophoblasts of normal human pregnancy, using forty-one hysterectomized pregnant uteri (6-22 weeks). In villous trophoblasts, the capacity to synthesize hCG alpha, hCG beta CTP, hPL and SP1 seemed to develop according to the morphological change from mononuclear cells to multinuclear cells. In contrast, the synthetic capacity of these proteins seemed not to correspond with the morphological change in extravillous trophoblasts: The location of hCG alpha, hCG beta CTP and SP1 was restricted to the mononuclear trophoblasts in the superficial decidua, while hPL was present extensively in extravillous trophoblasts, including multinuclear trophoblasts in the deciduomuscular junction. Therefore, it may be reasonably said that extravillous trophoblasts have many biological features distinct from villous trophoblasts and differentiate in an independent manner. Mononuclear trophoblasts in the cell column were negative for these proteins, which, together with morphological observations, strongly suggest the germinative nature of these cells.     

Cullin 7 and Fbxw 8 expression in trophoblastic cells is regulated via oxygen tension: implications for intrauterine growth restriction?

Objective: The F-box protein Fbxw8 is a cofactor of Cullin 7 (Cul7), which regulates protein transfer to the proteasome and cell growth. Cul7 or Fbxw8 deficiency is associated with intrauterine growth restriction (IUGR) due to abnormal placental development leading to poor oxygen supply to the fetus. We studied the role of hypoxia for Fbxw8 and Cul7 expression in trophoblastic cells. Methods: Immunomagnetic bead-separated extravillous trophoblast (EVT) and villous trophoblast (VT) and trophoblast cell lines were incubated with 1 or 8% O₂. Fbxw8 and Cul7 expression was determined in IUGR versus matched control placentas. Results: Fbxw8 was expressed uniformly in trophoblasts, whereas Cul7 expression was most prominent in trophoblast cell lines. Hypoxia reduced expression of Cul7 and Fbxw8 in all trophoblastic cells, except for villous trophoblasts. In vivo, Cul7 and Fbxw8 were detected in syncytiotrophoblast cells, VT, and EVT cells. Although no significant changes in expression levels of Fbxw8 or Cul7 were noted in IUGR compared with control placentas, Fbxw8 expression correlated negatively with gestational age in the control, but not in the IUGR group. Conclusion: Fbxw8 and Cul7 expression reveals a complex regulation in trophoblastic cells. Our findings suggest that dysregulation of Cul7 and Fbxw8 expression might affect trophoblast turnover in IUGR.