Accumulation and release of iron in polarly and non-polarly cultured trophoblast cells isolated from human term placentas.

We investigated the usefulness of membrane grown human term trophoblast cells in transferrin-mediated iron transfer studies. We showed that diferric transferrin is taken up both at the microvillous and at the basal membrane by means of receptor-mediated endocytosis. Uptake from the microvillous side is predominant. This corresponded with a much higher expression of transferrin receptors at the microvillous membrane as compared to the basal one. Iron appeared to accumulate in the cell. Accumulation was higher when transferrin was supplied at the microvillous side. Transfer of iron could not be assessed because uptake of transferrin by the cells was much less than passive diffusion of transferrin through the cell-free filter. The observation of iron accumulation was unexpected for a transfer epithelium. Could it be that part of the iron taken up by the cells is rapidly released whereas the remaining part accumulates? In this case the rate of iron uptake should be higher than the rate of iron accumulation. This question was assessed with non-polarly cultured trophoblast cells. We showed that like in polar cells iron accumulated in ferritin. A new experimental design enabled us to demonstrate that indeed the rate of transferrin-mediated iron is in excess over iron accumulation. We thus provide evidence for a mechanism that enables rapid transfer of iron across the syncytiotrophoblast cell layer.

Non-transferrin iron uptake by trophoblast cells in culture. Significance of a NADH-dependent ferrireductase.

This study shows that trophoblast cells in culture are able to take up 59Fe from both Fe(III)nitrilotriacetate (NTA) and Fe-ascorbate. Fe in the presence of ascorbate is assumed to be Fe(III) in equilibrium with Fe(II). Kinetic parameters for non-transferrin iron uptake are determined from initial rate experiments, yielding Vmax=366 pmol/mg protein/5 min and Km=0.96 microM for Fe(III)NTA and Vmax=4043 pmol/mg protein/5 min and Km= 1.3 microM for Fe-ascorbate. Since trophoblast cells in culture reduce extracellular Fe(III)CN, and uptake of 59Fe from Fe-ascorbate is higher than that from Fe(III)NTA, it is suggested that reduction of Fe(III) precedes uptake. Uptake of 59Fe from both Fe-ascorbate and Fe(III)NTA is inhibited by Fe(II)chelator ferrozine and membrane-impermeable Fe(III)CN, further supporting this hypothesis. Studies with microvillous membrane vesicles (MMV) and basal membrane vesicles (BMV) reveal the presence of a NADH-dependent ferrireductase. Reduction of Fe(III)CN follows Michaelis-Menten kinetics, both with respect to [NADH] and [Fe]. NADPH is ineffective as electron donor. The rate of Fe(III)CN reduction by BMV is 2.5 times higher compared to MMV, while Km values for Fe(III)CN and NADH are not significantly different. These results reveal that a transmembrane NADH-dependent ferrireductase plays a role in uptake of non-transferrin iron. The possibility that this enzyme system is involved in iron transfer across the basal membrane is discussed.

Morphological differentiation of cytotrophoblasts cultured in Medium 199 and in keratinocyte growth medium.

In culture, cytotrophoblast cells differentiate biochemically as well as morphologically into syncytiotrophoblast-like structures. Morphological and biochemical differentiation can be affected by the composition of the culture medium. The aim of this study was to analyze the morphological differentiation (syncytium formation) of cytotrophoblasts cultured in Medium 199 (M199) and keratinocyte growth medium (KGM). Term human cytotrophoblast cells were cultured in either M199 or KGM with daily refreshment of the media. Both media induced biochemical differentiation, as monitored by measuring hCG secretion. Syncytium formation was visualized by immunocytochemical staining of desmosomes (cell membranes). Cytotrophoblasts rapidly formed aggregates; however, single cells were seen throughout culture. Though the aggregates developed into syncytia, approximately 15% of the nuclei were still found in cell aggregates at the end of the culture period (4 days). The final percentage of nuclei in syncytia (60-70%) did not differ between the culture media used. Syncytium formation occurred more rapidly in KGM medium. Approximately 50% of the nuclei were found in syncytia after 40 and 50 h in KGM and M199, respectively. The number of nuclei per syncytium was slightly higher in M199, but the average surface area of the syncytia was larger in KGM cultured cells (162-132 mm2). These differences did not reach significance. We conclude that there is no major difference in morphological differentiation between cytotrophoblast cells in KGM or M199. Moreover, both media sustain equal rates of hCG secretion.

Transferrin in cultured human term cytotrophoblast cells: synthesis and heterogeneity.

Transferrin (Tf) mRNA was recently demonstrated in rat and mouse placental tissue. Rat placental cells were shown to secrete transferrin. The cell type with which Tf mRNA was associated was not investigated. We therefore studied the ability of immunopurified human term cytotrophoblast cells in culture to synthesize Tf, by means of pulse-label experiments with 35S-methionine and report that these cells do synthesize Tf. Tf mRNA was demonstrated in the cell lysates by means of RT-PCR. Tf isolated from cytotrophoblast and syncytiotrophoblast cells was shown to be different from both maternal and fetal serum Tf with respect to the distribution of isoforms as demonstrated by means of iso-electric focusing. The iso-electric points were found at lower pH values (pH 5.0-5.4), compared to the iso-electric points of maternal and fetal serum Tf, suggesting a higher degree of sialylation and glycan chain complexity.

Binding of human isotransferrin variants to microvillous and basal membrane vesicles from human term placenta.

Transferrin (Tf)-dependent iron transfer from mother to fetus is mediated by Tf receptors (TfRs) which are present on both microvillous and basal membranes of human placental syncytiotrophoblast. We used microvillous and basal membrane vesicles, both isolated from the same human term placenta, to investigate the binding of [125I]-labelled diferric bi-bi antennary tetra-sialo Tf (bb Tf), bi-tri-antennary penta-sialo Tf (bt Tf) and tri-tri-antennary hexa-sialo Tf (tt Tf). To diminish the effect of endogenous Tf, membrane vesicles were washed before binding of [125I]-Tf. The number of TfRs on microvillous membranes was 6.1 +/- 2.4 (mean +/- s.d., n = 15) times higher than that on basal membranes, whereas the affinity of TfRs on basal membranes was 3.9 +/- 0.4 (mean +/- s.d., n = 15) times higher than that of TfRs on microvillous membranes, irrespective the isoTf used. The affinity constants of TfRs on both microvillous and basal membranes were higher for bb Tf than for bt Tf and higher for bt Tf than for tt Tf. However, these latter differences were rather small and probably not of physiological importance.

Regulation of transferrin receptor synthesis by human cytotrophoblast cells in culture.

The aim of this study was to examine the capacity of the syncytiotrophoblast to regulate transferrin receptor (TfR) synthesis in response to modulations in maternal iron supply. The model used was the primary trophoblast cell culture. Trophoblast cells isolated from term human placentas were cultured in iron-poor (Medium 199), iron-depleted (desferrioxamine (DFO)) and iron-supplemented (diferric transferrin (hTf-2Fe), ferric ammonium citrate (FAC) medium. TfR synthesis was reduced in response to hTf-2Fe supplementation. FAC did not modulate TfR synthesis. Iron deprivation by DFO resulted in clear stimulation of TfR synthesis. These results show that the differentiating trophoblast cells respond to pertubations in the (transferrin-mediated) iron supply by adjustments in the rate of TfR synthesis. Taking syncytiotrophoblast in culture as model for the maternal/fetal interface in vivo, our results would suggest that the placenta is able to make short term adjustments of the capacity for iron uptake.

Uptake of cimetidine into syncytial microvillus membrane vesicles of human term placenta.

Uptake of the H2-receptor antagonist, cimetidine, into syncytial microvillus membrane vesicles of human term placenta was investigated to clarify whether an active transport mechanism can be responsible for the observed barrier of the human placenta for cimetidine. Imposition of an outwardly directed H(+)-gradient stimulated cimetidine uptake, resulting in a small transient overshoot. The H(+)-gradient-dependent peak uptake was decreased under voltage-clamped conditions by carbonyl cyanide p-trifluoromethoxy-phenylhydrazone, suggesting the presence of an organic cation-proton exchange mechanism. Uptake was partially, but significantly, inhibited by organic cation transport inhibitors, H2-receptor antagonists and several other cationic drugs, providing further evidence for mediated uptake. H(+)-gradient-dependent cimetidine uptake was saturable and characterized by a low-affinity (Km) of 6.3 mM and Vmax of 17.5 nmol/mg protein/10 sec. We conclude that the system cannot play an important role in the barrier function of the human placenta in the transport of cimetidine. Rather than active transport, other factors, as for instance the degree of ionization of cimetidine at physiological pH, seem to be a more likely explanation for the low clearance of cimetidine across the human placenta.

Ferritin in cultured human cytotrophoblasts: synthesis and subunit distribution.

The present study aims at the role of ferritin in the regulation of syncytiotrophoblast free iron levels. The differentiated cytotrophoblast cell in culture is used as a model for this maternal-fetal interface. Cytotrophoblast cells isolated from term placentae are cultured in iron-poor (Medium 199), iron-depleted [desferrioxamine(DFO)] and iron-supplemented [diferric transferrin (hTF-2Fe), ferric ammonium citrate (FAC)] medium. Distribution and de novo synthesis of isoferritins is studied, together with the cellular iron concentration and the ferritin iron saturation. Compared to ferritin isolated from total placenta, ferritin obtained from villous tissue is enriched with acidic isoforms. This observation is in agreement with measured light (L) to heavy (H) subunit ratios < 1 of de novo synthesized ferritin in cultured cytotrophoblast cells. Neither iron-poor culture medium, nor hTf-2Fe supplemented medium affects the cellular iron or ferritin concentration. FAC increased the cellular ferritin iron saturation and (by synthesis) the acidic isoferritin concentrations. The results strongly suggest, that the term syncytiotrophoblast is able to balance transferrin-mediated iron uptake and iron release. In case of FAC supplementation, the syncytiotrophoblast is unable to keep intracellular iron low, and ferritin synthesis is stimulated. The predominance of acidic ferritins and the preferential synthesis of H subunits can be functionally explained by the established fact that iron incorporation in acidic ferritins is faster due to the presence of ferroxidase centres. Damage by free iron catalysed hydroxyl radical formation is therefore minimized.