Expression of human placental G proteins during pregnancy

Signalling pathways regulating the invasive differentiation of human trophoblasts: a review

The invasive differentiation pathway of trophoblasts is an indispensable physiological process of early human placental development. Formation of anchoring villi, proliferation of cell columns and invasion of extravillous cytotrophoblasts into maternal decidual stroma and vessels induce vascular changes ensuring an adequate blood supply to the growing fetus. Extravillous trophoblast differentiation is regulated by numerous growth factors as well as by extracellular matrix proteins and adhesion molecules expressed at the fetal-maternal interface. These regulatory molecules control cell invasion by modulating activities of matrix-degrading protease systems and ECM adhesion. The differentiation process involves numerous signalling cascades/proteins such as the GTPases RhoA, the protein kinases ROCK, ERK1, ERK2, FAK, PI3K, Akt/protein kinase B and mTOR as well as TGF-beta-dependent SMAD factors. While an increasing number of signalling pathways regulating trophoblast differentiation are being unravelled, downstream effectors such as executing transcription factors remain largely elusive. Here, we summarise our current knowledge on signal transduction cascades regulating invasive trophoblast differentiation. We will focus on cell model systems which are used to study the particular differentiation process and discuss signalling pathways which regulate trophoblast proliferation and motility.

Overlay blot identification of GTP-binding proteins in mitochondria from human placenta

In this study, an overlay blot method was used to identify GTP-binding proteins in fractions of human placenta. Human placenta were fractionated by centrifugation into preparations containing (1) mitochondria, (2) nucleoli and (3) microsomes, plasma membrane and cytosol. GTP-binding proteins were detected by overlay blot using alpha32P-GTP. Proteins of 23 and 25 kDa were identified in all fractions and GTP binding was higher in the presence of 1.0, 2.5, 5.0 and 10.0 mM MgCl2 as compared to equivalent concentrations of CaCl2. In mitochondrial preparations binding of alpha32P-GTP to 23 and 25 kDa was displaced significantly by GDP and GTP but not ADP or ATP. Fractions containing microsomes, plasma membrane and cytosol displayed two labelled bands of 14 and 18 kDa that were not present in other fractions. These data indicate that the placenta contains specific GTP-binding proteins of molecular weights that are consistent with the small monomeric GTP binding protein family (18-36 kDa). Two of these are located in the mitochondria and may regulate the function of these organelles in the placenta.

Expression of human placental D2-dopamine receptor during normal and abnormal pregnancies

Previous studies have demonstrated the presence of D2-dopamine binding sites in the human placenta, and that dopamine (DA), via these D2-like receptors, inhibits both basal- and hormone-stimulated secretion of human placental lactogen (hPL) from trophoblastic cells. However, nothing is known about the ontogenesis of this placental D2-dopamine receptor (D2R) during pregnancy. Therefore, the aim of this study was to analyse the expression of these receptors throughout gestation in placentae from normal as well as abnormal pregnancies. Western and Northern blot analysis were performed on membrane protein and messenger RNA (mRNA) preparations of human placentae from various weeks of gestation as well as from pregnancies complicated by pre-eclampsia of hydatidiform mole. The autoradiographs of both proteins and mRNA showed differential expression of placental D2R during normal pregnancy. When the relative levels of D2R proteins were analysed throughout pregnancy, there was a significant but transient decrease of approximately 23 per cent of D2R content at 9-16 weeks of gestation with a return to baseline levels at 17-18 weeks. An increase in mRNA levels began at week 19 of gestation and reached a maximum value at term. During the first half of gestation, the relative levels of D2R mRNA (2.5 kb) showed an inverse pattern of expression when compared to D2R protein content. Specifically, the levels of D2R mRNA increased by approximately 26 per cent between weeks 9 and 16 of pregnancy in comparison with the values observed at 7-8 weeks, and returned to baseline levels at 17-18 weeks of gestation. The D2R relative protein levels subsequently increased from 19 to 30 weeks of gestation, and then remained stable. The autoradiographs of both proteins and mRNA showed significantly decreased expressions in placentae from both pre-eclamptic (approximately 45 per cent inhibition) and molar (approximately 0-70 per cent inhibition) pregnancies. Moreover, there was important variability in the expression of placental D2R from hydatidiform moles. Using immunological and molecular biology techniques, the present study confirms the presence of D2R in human placenta. The variations of placental D2R expression during normal and abnormal pregnancies argue for an important role of DA in human placental function, although this remains to be investigated further.

Interaction of D2-dopamine receptor with two pertussis toxin sensitive G proteins in human placenta

We have demonstrated the presence in human placenta of D2 dopamine receptors (D2R) which inhibit human placental lactogen (hPL) release. This inhibitory effect of dopamine (DA) was sensitive to pertussis toxin (PTX) indicating that it may be mediated by the Gi/Go family of G proteins. However, nothing is known on this G proteins/D2R interaction in human placenta. In this study, we demonstrate that DA (10(-4) M) inhibits by 39% the ADP-ribosylation by PTX of two G proteins of 40 and 41 kDa. This inhibition is receptor specific since it is reversed by spiperone, a D2R antagonist. Moreover we show that bromocriptine, a D2 agonist, inhibited the labeling of these two proteins in a dose-dependent manner with a maximal inhibition of 37% at a concentration of 10(-6) M. In order to understand the role of D2R in placental endocrinology, we have analyzed the interactions of these two PTX-sensitive G proteins with D2R in normal and abnormal pregnancies. The autoradiographs of both PTX ADP-ribosylated placental proteins of 40 and 41 kDa showed differential labeling during normal pregnancy. Thus, the relative levels of ADP-ribosylation by PTX of both proteins were 2.5 and 3.0 fold lower at term than those observed during first and second trimester whereas no difference was observed between the first and second trimester. Also, no significant change in the level of inhibition by DA was observed between 7-9 weeks and 18-40 weeks of pregnancies (35-45% inhibition). However, we observed a maximal inhibition between 10 to 17 weeks of pregnancy (64% inhibition). In placentas from preeclamptic pregnancies, the levels of ADP-ribosylation were similar to those observed in normal pregnancy, while the DA inhibition was increased by 24%. The levels of ADP-ribosylation in molar placentas reached 20% of normal values, while no difference in DA inhibition was observed. This study demonstrates that two distinct PTX-sensitive G proteins are coupled to human placental D2R. The physiological significance of the variations in these ADP-ribosylated-G proteins/D2R interaction during normal and preeclamptic pregnancies remains to be investigated.

Expression of G proteins in human placentas from pregnancies complicated by gestational hypertension

Preeclampsia (gestational hypertension) is accompanied by decreased hPL and increased hCG levels in maternal serum. The expression of these peptides as well as the endocrine mechanisms responsible for their regulation in preeclampsia are unknown. We have demonstrated that regulatory GTP-binding proteins (G proteins) are implicated in the modulation of hPL production by placentas from normal pregnancies. In order to extend our knowledge on placental endocrinology, we analyzed in this study the expression of hPL and beta-hCG mRNAs as well as placental G protein alpha-subunits in pregnancies complicated by gestational hypertension. Western and Northern blot analyses were respectively performed on membrane protein and total mRNA preparations from human placentas of preeclamptic (n = 7) and normal pregnancies (n = 4). The levels of hPL and beta-hCG mRNAs were respectively 108% and 105% of those from normal placentas, suggesting that the altered circulating levels of hPL and beta-hCG are not related to dysfunctional mRNA expression of these peptides. The autoradiographs for G proteins and their mRNAs showed no difference in G protein expression between preeclamptic and normal tissues. Specifically, G alpha i2, G alpha i3, G alpha o, G alpha s, and G alpha q/11 levels reached 87%, 81%, 91%, 99%, and 103% respectively of those from normal placentas. In parallel with the protein levels, their mRNAs expression were respectively 93%, 89%, 113%, 104%, and 94% of normal values for G alpha i2, G alpha i3, G alpha o, G alpha s, and G alpha q/11. These results suggest that neither a change in hPL and beta-hCG expression nor a change in signal transduction machinery is implicated in the altered circulating levels of hPL and beta-hCG in preeclampsia.

Expression of G proteins in human placentae from molar pregnancies

Hydatidiform mole is a conceptus, usually devoid of an intact fetus, with variable proliferation of trophoblast and altered placental protein synthesis, including high human chorionic gonadotropin (hCG) and low human placental lactogen (hPL) production. Little is known about the control of the production of these two placental proteins in molar pregnancies. Regulatory guanine 5'triphosphate (GTP)-binding proteins (G proteins) play key roles in the endocrine control of peptide production by the placenta. The present authors recently demonstrated that Gi2, Gi3 Go, and Gs alpha-subunits were expressed in normal human placenta throughout pregnancy. This study analysed the expression of placental G protein alpha-subunits in molar pregnancies. Western and Northern blot analyses were performed on membrane protein and total mRNA preparations of human placentae, respectively, from hydatidiform mole (n = 5) and normal pregnancies (n = 4). The levels of hPL and beta-hCG mRNAs were 60 and 237 per cent respectively, of those from normal placentae. The autoradiographs for G proteins and their mRNAs showed decreased expression in molar placentae in comparison with normal tissues. Specifically, G alpha i2, G alpha i3, G alpha o, and G alpha s levels reached 39, 4, 42, and 89 per cent, respectively, of those from normal placentae. In parallel with the protein levels, their mRNAs expression were 8, 3, 54 and 65 per cent of normal values for G alpha i2, G alpha i3, G alpha o, and G alpha s, respectively. The results demonstrate important changes in placental G protein expression in hydatidiform moles suggesting alterations in the signal transduction machinery within the molar trophoblast.