Hans-Werner Denker

Interactions between trophoblast and uterine epithelium: monitoring of adhesive forces.

At embryo implantation, it is postulated that the initial contact between blastocyst and maternal tissues is by adhesion of the trophoblast to the uterine epithelium. This cell-to-cell interaction is thought to be critical for implantation, although the actual adhesive forces have never been determined. In the present study, the atomic force microscope (AFM) was used to study the adhesion between human uterine epithelial cell lines (HEC-1-A; RL95-2) and human trophoblast-type cells (JAR). Specific interaction forces of these epithelia via their apical cell poles were determined on the basis of approach-and-separation cycles. For this purpose, the AFM tip was functionalized with JAR cells, then brought to the surface of uterine epithelial monolayers and was kept in contact for different periods of time (ms, 1, 10, 20, 40 min). The approach force curves displayed repulsive interactions for both HEC-1-A and RL95-2 cells. However, RL95-2 cells (with a smooth surface structure and a thin glycocalyx) showed lower values of the repulsive regime than HEC-1-A cells (with a rough surface structure and a thick glycocalyx). After having overcome repulsive interactions, the initial contact was followed by adhesive interactions. For contact times of 20 and 40 min, RL95-2 cells, but not HEC-1-A cells, showed specific JAR binding, i.e. the separation force curves displayed repeated rupture events in the range of 1-3 nN with a distance between 7-15 microm and, thereafter, a final rupture event at a distance of up to 45 microm. These features point to the formation of strong cell-to-cell bonds. Collectively, these studies provide the first definition of interaction forces between the trophoblast and the uterine epithelium, and are consistent with the hypothesis that an RL95-2-like architecture of uterine epithelial cells, i.e. an non-polarized phenotype, is essential for apical adhesiveness for the human trophoblast.

Adhesion and invasion of three human choriocarcinoma cell lines into human endometrium in a three-dimensional organ culture system.

A novel in vitro model was developed to study attachment and invasion of choriocarcinoma cell spheroids using pre-cultured secretory phase human endometrium as a host tissue. During pre-culturing in shaker culture human endometrium had regenerated a complete epithelial covering and had shed cells damaged during explantation. Spheroids of three human choriocarcinoma cell lines (BeWo, Jeg-3, JAr) which displayed linear growth in culture and produced placental hormones were used in this study as models for trophoblast behaviour. Morphological differences were noted in the spheroids from the three choriocarcinoma cell lines; BeWo and Jeg-3 spheroids exposed flattened and more differentiated cells on their surfaces while superficial cells in JAr spheroids maintained their cytotrophoblast-like morphology. Spheroids from all three cell lines were proven to be invasive in a general invasion assay using embryonic chick heart fragments, with JAr spheroids being the most aggressive. When spheroids were confronted with pre-cultured re-epithelialized endometrial fragments, however, Jeg-3 spheroids showed the highest incidence of attachment (52%) and the greatest amount of invasion into the underlying stroma. BeWo spheroids also attached (37%) and penetrated the epithelium, but did not invade into the stroma. JAr spheroids showed a minor degree of attachment (12%) and little or no invasion into the stroma. These results show that the three choriocarcinoma cell lines, although all invasive in a general invasion assay, differ in adhesion to uterine epithelium and invasion into endometrial stroma. This model offers opportunities for studying mechanisms of trophoblast adhesion and invasion, using human endometrium as the natural host tissue.

Trophoblast - Endometrial Interactions at Embryo Implantation: A Cell Biological Paradox

Invasion of the trophoblast into the endometrium, which forms an essential element of embryo implantation in most mammalian species including the human, has long impressed investigators. It resembles invasion of malignant tumors in many respects, including host tissue destruction, blood vessel erosion, a certain degree of repair processes and neovascularization (cf. Denker, 1977, 1980, 1983). It presents an immunologic paradox appearing to violate transplantation laws: antigenically different cells being tolerated within a basically immunocompetent milieu (cf. Bulmer et al., 1990; Loke et al., 1990).

Differential Expression and Localization of Integrins and CD44 in the Membrane Domains of Human Uterine Epithelial Cells During the Menstrual Cycle

Human uterine epithelium displays a distinctly polarized organization with basal, lateral, and apical plasma membrane domains. Although nonadhesive throughout most of the menstrual cycle, uterine epithelial cells allow attachment of trophoblast cells to their apical pole during embryo implantation. Development of the receptive state might involve expression of cell adhesion molecules and/or redistribution of such molecules with respect to their localization at the basal, lateral, and apical membrane domains of cells. Expression and distribution of alpha 1-, alpha 3-, alpha 5-, alpha 6-, beta one-, beta 3- and beta 4-integrin subunits as well as of CD44 were examined in the luminal epithelium of human endometrium by immunohistochemistry in different phases of the menstrual cycle. The luminal epithelium was found to express alpha 1-, alpha 3-, alpha 6-, beta 1-, beta 4-integrin subunits and CD44. alpha l6-Integrin subunits and CD44 displayed cycle dependency. The alpha 6-integrin subunits were detected in the basal membrane domains in all phases. However, in correlation with increasing expression during the secretory phase of cycle, these subunits newly appeared in the lateral membranes of epithelial cells. CD44 showed increased expression in the secretory phase but was always restricted to the lateral membranes. The conspicuous behavior of alpha 6-integrin subunits and CD44 is discussed with respect to its possible functional significance for embryo implantation, and in relation to a hypothesis postulating that steroid-controlled master genes direct the acquisition of the receptive state of the luminal uterine epithelium by changing elements of the apicobasal polarity of these cells.

Structural dynamics and function of early embryonic coats.

The extracellular embryonic coats (embryo/blastocyst coverings) that surround early mammalian embryos are most often still referred to as zona pellucida. Accumulating evidence from a number of earlier and recent studies clearly indicates that this is an oversimplification which cannot be defended anymore, at least in many species. Structural modifications of the coats occur during cleavage and blastocyst stages; these are most obvious in a number of species with the central type of implantation and, related to this, a high degree of blastocyst expansion, notably the rabbit and the horse. In this contribution, formation and transformation of the various layers of coats (zona pellucida, mucoprotein layer, neozona and gloiolemma in the rabbit, capsule in the horse) will be reviewed, as will be comparable structures seen, e.g., in the fur seal (subzonal layer) and the baboon. These phenomena will be discussed in the context of structurally more subtle changes found in other species, including those with small blastocysts and other types of implantation, in particular with biochemical modifications which may be physiologically quite important. The molecular mechanisms of deposition of coats and their transformation and shedding/dissolution will be briefly addressed. The possible functional significance of the coats and their transformation will be discussed (mechanical, morphogenetic and immunological role, molecular transport control, blastocyst positioning, implantation, trap and reservoir function for signalling molecules).

Quantitation of human choriocarcinoma spheroid attachment to uterine epithelial cell monolayers

SummaryAdhesive interactions of trophoblast cells with the endometrium are essential for embryo implantation in the uterus. Choriocarcinoma cells, the malignant counterpart of trophoblast, show pronounced invasiveness and are of interest for model studies. We describe here an in vitro model system for the study of adhesion of human JAR choriocarcinoma multicellular spheroids to different human endometrial epithelial cell lines (RL95-2, HEC-1A, KLE, AN3-CA) grown as monolayers. Cell characterization showed JAR spheroids to secrete the placental hormones human chorionic gonadotropin and progesterone into the culture medium; distinct patterns of keratin, vimentin, and uvomorulin expression were seen in the endometrial cell lines. Spheroid attachment to endometrial monolayers was quantified using a centrifugal force-based adhesion assay, and morphology was examined by light and electron microscopy. Results showed the JAR spheroids to attach to three of the endometrial monolayers (RL95-2, HEC-1A, KLE) progressively over a 24-h period (by which time ≥80% of the spheroids attached). Significant differences in spheroid attachment were most pronounced at 5 h (RL95-2 > HEC-1A > KLE and poly-d-lysine control, i.e. 90:45:17:17% attached). JAR spheroids did not attach to the endometrial cell line AN3-CA. Morphology revealed choriocarcinoma cells to begin to intrude between the uterine RL95-2 epithelial cells at 5 h. At 24 h, this intrusive type of penetration continued to be seen only with the RL95-2 monolayer. The assay system thus identifies differences in attachment properties between choriocarcinoma cells and various endometrial cell lines and forms the basis for further studies on the molecular interactions involved.Adhesive interactions of trophoblast cells with endometrium are essential for embryo implantation in the uterus. Choriocarcinoma cells, the malignant counterpart of trophoblast, show pronounced invasiveness and are of interest for model studies. We describe here an in vitro model system for the study of adhesion of human JAR choriocarcinoma multicellular spheroids to different human endometrial epithelial cell lines (RL95-2, HEC-1A, KLE, AN3-CA) grown as monolayers. Cell characterization showed JAR spheroids to s++ecrete the placental hormones human chorionic gonadotropin and progesterone into the culture medium; distinct patterns of keratin, vimentin, and uvomorulin expression were seen in the endometrial cell lines. Spheroid attachment to endometrial monolayers was quantified using a centrifugal force-based adhesion assay, and morphology was examined by light and electron microscopy. Results showed the JAR spheroids to attach to three of the endometrial monolayers (RL95-2, HEC-1A, KLE) progressively over a 24-h period (by which time > or = 80% of the spheroids attached). Significant differences in spheroid attachment were most pronounced at 5 h (RL95-2 > HEC-1A > KLE and poly-D-lysine control, i.e. 90:45:17:17% attached). JAR spheroids did not attach to the endometrial cell line AN3-CA. Morphology revealed choriocarcinoma cells to begin to intrude between the uterine RL95-2 epithelial cells at 5 h. At 24 h, this intrusive type of penetration continued to be seen only with the RL95-2 monolayer. The assay system thus identifies differences in attachment properties between choriocarcinoma cells and various endometrial cell lines and forms the basis for further studies on the molecular interactions involved.

Adhesion of trophoblast to uterine epithelium as related to the state of trophoblast differentiation: In vitro studies using cell lines

At the initial phase of embryo implantation, the trophoblast must have acquired competence for adhesion to the uterine epithelium, a condition whose cell biological basis is far from understood. In the present study, trophoblast‐type cells (BeWo, JAr, and Jeg‐3 choriocarcinoma cell lines) were treated with retinoic acid, methotrexate, dibutyryl‐cAMP, or phorbol‐12‐myristate‐13‐acetate in order to modulate their ability to adhere to uterine epithelial cells (RL95‐2). In an established model, multicellular spheroids of choriocarcinoma cells were transferred onto the surface of monolayer cultures of RL95‐2 cells followed by a centrifugal force‐based adhesion assay. In controls, about 45% of BeWo and JAr cell spheroids and 75% of Jeg‐3 spheroids adhered to uterine monolayers within 30 min. Pretreatment of spheroids with either of the agents stimulated differentiation as indicated by the rate of chorionic gonadotropin secretion, but consistently reduced the adhesion to the endometrial monolayer in all three choriocarcinoma cell lines. While previous investigations had shown that invasiveness of trophoblast cells (into extracellular matrix) does not seem to be linked to the differentiation program in a simple manner, the present data suggest that such an (inverse) link may indeed exist with respect to the ability to initiate an adhesive interaction with the uterine epithelium. These observations support the view that epithelial cell interactions as typical for the initial phase of embryo implantation are regulated in a way that is clearly different from cell–matrix interactions governing later phases of trophoblast invasion into the endometrial stroma Mol. Reprod. Dev. 57:135–145, 2000.

In vitro Studies on Endometrial Adhesiveness for Trophoblast: Cellular Dynamics in Uterine Epithelial Cells

Initiation of embryo implantation involves adhesion of trophoblast cells to the epithelial lining of the endometrium. The mechanisms regulating the adhesive properties of the uterine epithelium for trophoblast during initiation of human embryo implantation, however, are still incompletely understood. We report here on model studies that we have performed in our laboratory, and in particular on certain methodological approaches that seem to yield new insight into basic mechanisms involved. Of central interest is the ability of the uterine epithelium to develop an adhesion competence at its apical cell pole. This confronts us with a cell biological paradox in that adhesion must be established at the pole which in simple epithelia is typically specialized to resist adhesion. Gain of apical adhesion competence by uterine epithelial cells should be related to cellular rearrangements, i.e. a modulation of their apicobasal cell polarity. Here, we used monolayer-cultured uterine epithelial RL95-2 cells as an in vitro model for the human receptive uterine epithelium. We demonstrated that formation of stable cell-to-cell bonds between the free (apical) pole of these cells and attaching trophoblast (modelled by JAr cells) depends on a number of structural and functional peculiarities that RL95-2 cells have in contrast to other uterine epithelial cells (HEC-1-A cells) which resist attachment via this cell pole. RL95-2 cells were shown to lack tight junctions and to exhibit only rudimentary adherens junctions and a non-polar organization of the actin cytoskeleton. Using the atomic force microscope in a force spectroscopy mode, we exactly defined the time dependence of adhesive interactions between RL95-2 cells and trophoblast, measured the pressure force needed to initiate this process, and screened the buildup of the adhesive forces between the binding partners. A dynamic interaction between the actin cytoskeleton and integrins (a prerequisite for functional activity of integrins) was shown to be an important aspect of the adhesive properties of RL95-2 cells. In addition, at least two types of calcium channels in the plasma membrane of RL95-2 cells seem to play a role in activation of a variety of calcium-sensitive response mechanisms including adhesiveness for trophoblast, i.e. diltiazem-sensitive channels seem to contribute to the initiation of JAr cell binding and SKF-96365-sensitive channels to participate in a feedback loop that controls the balance of bonds. By extrapolation, these data suggest an active role of the uterine epithelium in the process of embryo implantation which we are just beginning to understand in terms of its cell biology.

Gap junction formation in rabbit uterine epithelium in response to embryo recognition

Gap junction formation was studied in the uterine epithelium of nonpregnant, pregnant, and pseudopregnant rabbits in the periimplantation phase (6, 7, 8 days post coitum/post human gonadotropin injection) using freeze-fracture and immunocytochemistry as well as intracellular Lucifer yellow injection. At implantation (7 days post coitum) the uterine epithelial cells of the implantation chamber become junctionally coupled as evidenced by all three methods used. Gap junction protein (26K) becomes detectable immunocytochemically with a monoclonal antibody at 6 days post coitum in the epithelium surrounding the blastocyst, i.e., in the forming implantation chamber. The same sequence of events, starting with the presence of the gap junction protein before cell-to-cell coupling becomes evident, was observed in the blastocyst-free segments 1 day later. In contrast, uterine epithelium of nonpregnant and pseudopregnant animals in comparable phases shows an extremely low degree of coupling. The presence of the blastocyst is a necessary condition for the induction of gap junctions as demonstrated by unilateral pregnancy produced by tubal ligation. Thus, gap junction formation is one of the first maternal responses to a locally acting signal of the blastocyst.

Epithelial-mesenchymal transition in colonies of rhesus monkey embryonic stem cells : A model for processes involved in gastrulation

Rhesus monkey embryonic stem (rhES) cells were grown on mouse embryonic fibroblast (MEF) feeder layers for up to 10 days to form multilayered colonies. Within this period, stem cell colonies differentiated transiently into complex structures with a disc‐like morphology. These complex colonies were characterized by morphology, immunohistochemistry, and marker mRNA expression to identify processes of epithelialization as well as epithelial–mesenchymal transition (EMT) and pattern formation. Typically, differentiated colonies were comprised of an upper and a lower ES cell layer, the former growing on top of the layer of MEF cells whereas the lower ES cell layer spread out underneath the MEF cells. Interestingly, in the central part of the colonies, a roundish pit developed. Here the feeder layer disappeared, and upper layer cells seemed to ingress and migrate through the pit downward to form the lower layer while undergoing a transition from the epithelial to the mesenchymal phenotype, which was indicated by the loss of the marker proteins E‐cadherin and ZO‐1 in the lower layer. In support of this, we found a concomitant 10‐fold upregulation of the gene Snail2, which is a key regulator of the EMT process. Conversion of epiblast to mesoderm was also indicated by the regulated expression of the mesoderm marker Brachyury. An EMT is a characteristic process of vertebrate gastrulation. Thus, these rhES cell colonies may be an interesting model for studies on some basic processes involved in early primate embryogenesis and may open new ways to study the regulation of EMT in vitro.