Junctions and adhesion molecules in first trimester and term human placentas.

Placental tight and gap junctions and their adhesion molecules were studied by immunochemistry and electron microscopy in early and term placentas in order to clarify their pattern of expression during placental development. Early syncytio-cytotrophoblast contained tight junctions with occludin and gap junctions with connexins 40 and 43. At term, endothelial cells from arterioles had tight and gap junctions following each other. Occludin, claudins 3 and 5 were found at the paracellular clefts of endothelial cells together with connexins 32, 40 and 50. Stromal cells had mixed tight and gap junctions with connexins 32, 43, 50. Capillaries demonstrated interendothelial tight junctions with claudins 3 and 5, and small gap junctions. Taken together these observations showed that the numerous tight and gap junctions of the early placental syncytio-cytotrophoblast are observed in the foetal arterioles and capillaries in the term placenta. We conclude that the tightness of the placenta due to the junctions lying in the syncytio-cytotrophoblast in early pregnancy is maintained by the foetal endothelial layer in term pregnancy, with significant developmental changes of their transmembrane proteins.

Characterization of first trimester human fetal placental vessels using immunocytochemical markers.

Cell differentiation markers on placental villi from the first trimester of human pregnancy have been studied by indirect immunofluorescence. Fluorescence labelling with antibodies against CD34 and CD31 was conspicuous in the vascular cells. The vascular paracellular clefts were labelled by anti-cadherin-5. A few vascular cells exhibited a positive reaction for von Willebrand factor, high-molecular-weight melanoma-associated-antibody and alpha-sm-actin compared to term pregnancy, indicating changes in protein expression during vascular differentiation. The poor anti-collagen IV reaction and the absence of a sm-myosin fluorescent signal observed around the vessels confirned the immaturity of the vessels. In contrast, strong reactions have previously been obtained with the latter antibodies in similar locations using term placental villi. A labelling was observed for antibodies against alpha3 and alpha5 integrins in these immature placental vessels suggesting cell-matrix interactions with specific domains of laminin or fibronectin. The vascular cells were also stained by anti-CD26. Surprisingly, the fetal vascular cells exhibited immunostainings in common with the villous cytotrophoblast (CD26) or the syncytiotrophoblast (cadherin-5) and cell islands cytotrophoblast (CD31, cadherin-5, alpha3 and alpha5 integrin subunits). These observations suggested a two step process for fetal vasculogenesis in the villi: i/ the formation of peripheral vessels induced by growth factors or cytokines derived from the nearby trophoblast, ii/ the development of muscular vessels due to growth factors or cytokines production induced by circulatory changes.

Isolation of villous microvessels from the human placenta.

A method for isolating the microvessels of the human placental villi has been developed in order to culture perivascular cells. It consists of an initial selection of the villi by serial sieving. The villi retained by the 75 microns sieve were digested by collagenase-dispase. A Percoll gradient permitted the isolation of microvessels still surrounded by stromal fibres and cells. Another digestion by collagenase-dispase eliminated the contaminant elements and allowed, after a new Percoll gradient, microvessels with endothelium, basement membrane and a few perivascular cells to be obtained. Each step of the isolation of microvessels was monitored by light or electron microscopy. Our study confirms the isolation of microvessels embedded in their basement membrane and the preservation of endothelial and perivascular cells after digestion. This method, which has permitted the culture of placental endothelial cells and pericytes, appears of interest for studying microvascular angiogenesis and permeability.

Phenotype of cultured fetal perivascular cells from human placenta studied by scanning electron microscopy.

The phenotype of perivascular placental cells has previously been studied using tissue sections from the fetal villi. The examination of these cells in culture by scanning electron microscopy gives us the opportunity to observe their three-dimensional phenotypes and associations outside their normal constraints. Human umbilical endothelial cells, which have a phenotype comparable to that observed in other studies, seem more flattened in culture than in their usual environment. Microvascular endothelial cells did not attain an epithelioid phenotype with close contacts between cells but formed a network of branched, elongated cells with phagocytotic activity. Some circular associations were observed when using a gelatinized matrix. Microvascular pericytes were large, flattened cells with an irregular border that pushed up nodular associations on a gelatin matrix. Chorioplacental myocytes adopted a network template comparable to that developed by microvascular endothelial cells. However, these elongated cells were thicker, without microvilli, and superficial filaments could be observed. In culture, confluent endothelial cells from the umbilical cord or microvascular pericytes associated as nodules reached a cell phenotype close to their in vivo counter-parts. This attainment of an in vivo phenotype remains questionable for chorioplacental myocytes. Microvascular endothelial cells, however, though there was sparse formation of circular associations, remained far from their in vivo phenotype.