Polytene chromosomes in mouse trophoblast giant cells

Mouse trophoblast giant cells undergo successive rounds of DNA replication resulting in amplification of the genome. It has been difficult to determine whether giant cell chromosomes are polyploid as in liver cells or polytene as in Dipteran salivary glands because the chromosomes do not condense. We have examined the pattern of hybridization of mouse giant cells with a variety of in situ chromosome markers to address this question. Hemizygous markers displayed one hybridization signal per nucleus in both diploid and giant cells, while homozygous markers displayed two signals per nucleus in both cell types. These patterns are consistent with cytological evidence indicating that giant cell chromosomes are polytene rather than polyploid. However, in contrast to the situation in Dipteran salivary glands, the two homologues do not appear to be closely associated. We conclude that the mechanism of giant cell DNA amplification involves multiple rounds of DNA replication in the absence of both karyokinesis and cytokinesis, and that sister chromatids, but not homologous chromosomes, remain closely associated during this process.     

Placental villous mesenchymal cells trigger trophoblast invasion

The successful transformation of uterine spiral arteries by invasion trophoblasts is critical for the formation of the human hemochorial placenta. Placental trophoblast migration and invasion are well regulated by various autocrine/paracrine factors at maternal–fetal interface. Human placental multipotent mesenchymal stromal cells (hPMSCs) are a subpopulation of villous mesenchymal cells and have been shown to produce a wide array of soluble cytokines and growth factors including HGF (hepatocyte growth factor). The function of hPMSCs in placental villous microenvironment has not been explored. The interaction between hPMSCs and trophoblasts was proposed in vitro in a recent article. HGF produced by hPMSCs was able to engage c-Met receptor on trophoblast and induced the trophoblast cAMP expression. The cAMP activated PKA, which in turn, signaled to Rap1 and led to integrin β1 activation. The total integrin β1 protein expression by trophoblasts was not affected by HGF stimulation. Hypoxia downregulated HGF expression by hPMSCs. HGF and PKA activator 6-Bnz-cAMP increased trophoblast adhesion and migration that were inhibited by PKA inhibitor H89 or Rap1 siRNA. Thus, hPMSCs-derived paracrine HGF can regulate trophoblast migration during placentation. These findings provided insight revealing at least one mechanism by which hPMSCs implicated in the development of preeclampsia.     

Interplay between neutrophils and trophoblast cells conditions trophoblast function and triggers vascular transformation signals

Normal placentation entails highly regulated interactions of maternal leukocytes with vascular and trophoblast cells to favor vascular transformation. Neutrophil activation and neutrophil extracellular trap (NET) formation associate with poor placentation and severe pregnancy complications. To deepen into the mechanisms of trophoblast–neutrophil interaction, we explored the effects of NETs on trophoblast cell function and, conversely, whether trophoblast cell-derived factors condition neutrophils to favor angiogenesis and anti-inflammatory signals required for fetal growth. NETs isolated from activated neutrophils hindered trophoblast cell migration. Trophoblast conditioned media prevented the effect as well as the vasoactive intestinal peptide (VIP) known to regulate trophoblast and neutrophil function. On the other hand, factors released by trophoblast cells and VIP shaped neutrophils to a proangiogenic profile with increased vascular endothelial growth factor synthesis and increased capacity to promote vascular transformation. Results presented here provide novel clues to reconstruct the interaction of trophoblast cells and neutrophils in vivo during placentation in humans.     

Placental villous mesenchymal cells trigger trophoblast invasion

The successful transformation of uterine spiral arteries by invasion trophoblasts is critical for the formation of the human hemochorial placenta. Placental trophoblast migration and invasion are well regulated by various autocrine/paracrine factors at maternal–fetal interface. Human placental multipotent mesenchymal stromal cells (hPMSCs) are a subpopulation of villous mesenchymal cells and have been shown to produce a wide array of soluble cytokines and growth factors including HGF (hepatocyte growth factor). The function of hPMSCs in placental villous microenvironment has not been explored. The interaction between hPMSCs and trophoblasts was proposed in vitro in a recent article. HGF produced by hPMSCs was able to engage c-Met receptor on trophoblast and induced the trophoblast cAMP expression. The cAMP activated PKA, which in turn, signaled to Rap1 and led to integrin β1 activation. The total integrin β1 protein expression by trophoblasts was not affected by HGF stimulation. Hypoxia downregulated HGF expression by hPMSCs. HGF and PKA activator 6-Bnz-cAMP increased trophoblast adhesion and migration that were inhibited by PKA inhibitor H89 or Rap1 siRNA. Thus, hPMSCs-derived paracrine HGF can regulate trophoblast migration during placentation. These findings provided insight revealing at least one mechanism by which hPMSCs implicated in the development of preeclampsia.     

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.     

Uptake of protein by cultured human trophoblast cells

The uptake of peroxidase by cultured human trophoblast cells was monitored ultrastructurally. There was no apparent effect on the distribution of peroxidase caused by treatment at 4 degrees C, with KCN or with IgG. Pinocytic channels penetrate deep into the perinuclear cytoplasm and may act to allow pinocytosis to occur within layers of microfilaments which might otherwise prevent pinosome access to the majority of the synthetic organelles.     

Identification of extra-villous trophoblast cells in human decidua using an apparently unique murine monoclonal antibody to trophoblast

Summary Murine monoclonal antibodies were raised to human first trimester trophoblast cells. Eleven antibodies reacted with first trimester trophoblast, tested by immunoperoxidase staining on frozen sections, but only one had apparent specificity for trophoblast after examining reactivities with a panel of other cells and tissues. This antibody, designated FD0161G, bound selectively to syncytiotrophoblast and non-villous trophoblast in first trimester and term placentae. Villous cytotrophoblast was negative. This was clearly demonstrated on freeze-dried, paraffin embedded tissue sections which have superior architecture to frozen sections. FD0161G reacted with extra-villous trophoblast cells in human decidua which are also delineated by a monoclonal anti-cytokeratin antibody. Unlike the latter, however, FD0161G did not react with decidual glands. Thus FD0161G could be used as a specific probe for extra-villous trophoblast in decidual tissue     

Polyploidization and endomitosis in giant cells of rabbit trophoblast

Morphological and cytophotometric investigations have been performed on giant cells of the rabbit trophoblast to reveal a mechanism of nuclei polyploidization and define the level of polyploidy. The character of endomitotic chromosomes is found to differ and depend largely on the degree of nuclei polyploidy. Small chromosomes were found in nuclei with low levels of polyploidy. For highly polyploid nuclei, two stages are distinguished. In the first case condensed chromosomes join into bundles resembling Riesenchromosomen in plants, whereas in the second, decondensed chromosomal threads separate and disperse in the karyoplasm. The splitting does not involve nuclei-forming chromosomes in the region of the nucleolar organiser. The degree of polyploidy was determined on the 15th day of development. It was found that giant cell nuclei contain DNA in amounts corresponding to 32-512 chromosomal sets. Most of the nuclei have levels of 128c and 256c. Highly-polyploid nuclei disintegrate into small nuclei with the degree of polyploidy varying from 1c to 32c. Di- tri- and tetraploid nuclei predominate.