1 Department of Gynecology and Obstetrics, Faculty of Medicine, 2 Institute for Frontier Medical Science, Kyoto University, Sakyo-ku and 3 Daigo Watanabe Hospital, Fushimi-ku, Kyoto, Japan
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Abstract |
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Key words: early pregnancy/embryo invasion/HCG/PBMC
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Introduction |
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Recently, we have reported that spleen cells derived from pregnant mice promote murine embryo implantation by regulating endometrial receptivity (Takabatake et al., 1997a,b
). In humans, luteal cells in the corpus luteum during pregnancy express several cell adhesion molecules for T-lymphocytes on their cell surfaces (Fujiwara et al., 1993
; Hattori et al., 1995
; Higuchi et al., 1999
). PBMC derived from women in the early stage of pregnancy promoted progesterone production by luteal cells of the corpus luteum during pregnancy as much as did human chorionic gonadotrophin (HCG) in vitro, implying that the function of the corpus luteum of pregnancy is maintained not only by HCG, but also by PBMC (Hashii et al., 1998
). From these findings, we proposed the new hypothesis that peripheral immune cells receive signals from the conceptus in the early stage of pregnancy, then regulate the differentiation of both corpus luteum and endometrium to support embryo implantation (Hattori et al., 1995
; Takabatake et al., 1997b
, Hashii et al., 1998
).
In this study, to elucidate the physiological roles of PBMC in the embryo at the implantation site, we examined the effects of PBMC obtained from women in the early stage of pregnancy on embryo invasion by invasion assay using murine embryos. In addition, to examine how PBMC are activated by the embryo, we investigated the effect of HCG on PBMC, which is an embryonal signal.
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Materials and methods |
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HCG pretreatment of PBMC
PBMC derived from women in the secretory phase (n = 6, cycle day 1624) were cultured with recombinant HCG (rHCG; Rohto Phamaceutical Co. Ltd., Osaka, Japan; 0 and 10 IU/ml) in RPMI 1640 medium supplemented with 10% FCS for 48 hours at 37°C in a humidified atmosphere of 5% CO2 in air. After culture, the cells were collected and washed (x4) with the same medium as described above. PBMC were then suspended at a concentration of 1x106 cells/ml and were used for invasion assays.
Preparation of mouse blastocysts
Mouse blastocysts were prepared as previously reported (Takabatake et al., 1997a). Briefly, 4-week-old female and 3-month-old male ICR mice were purchased from Charles River Japan Inc. (Kanagawa, Japan). They were housed under controlled lighting (14 h light, 10 h dark) and given water and food ad libitum. Blastocysts were recovered from donor ICR mice (pregnancy day 4), which were 5 weeks old and had been mated after stimulation by pregnant mares serum gonadotrophin (PMSG) (5 IU; Teikokuzoki Co., Tokyo, Japan) and HCG (5 IU; Teikokuzoki Co.).
Invasion assay
The invasion assay was carried out as previously described, with slight modifications (Katsuragawa et al., 1997). As shown in Figure 1
, blastocysts were cultured on cell culture inserts (three blastocysts per culture insert, 6.4 mm in diameter, Becton Dickinson Labware, Bedford, MA, USA) containing polyethylene terephthalate membranes with 8 µm diameter pores, and these culture inserts were placed in each well of a 24-well tissue culture plate (Corning Costar Co., Cambridge, MA, USA). The upper surface of the filters was coated with cold Matrigel (15 µg/filter, Collaborative Research Co., Bedford, MA, USA) and air-dried aseptically. Prior to use, the inserts were rehydrated with 100 µl of warm RPMI 1640 for 2 h. Three blastocysts suspended in 500 µl of RPMI 1640 with 10% FCS were added to the filter coated with Matrigel (three embryos in each insert). Under the Matrigel, PBMC (1.2x106 cells in 1200 µl of RPMI 1640 with 10% FCS), which were prepared from non-pregnant women or pregnant women as described above, or culture medium only (control) were added to each culture well. In each experiment, one pair of blood samples from pregnant and non-pregnant women was used. The invasion assay was performed under the hypo-oxygenic conditions (5% O2, 5% CO2 and 90% N2) to prevent embryos from oxygenic toxicity (Nakayama et al., 1998
, 1999
). Every 24 h, spreading areas were measured by video micrometer (VM-50; Olympus, Tokyo, Japan) (Figure 2
). After 7 days of culture, the upper surface of the filter was `scrubbed' three times with a cotton swab. Cells remaining on the lower surface of the filter, which had migrated through the Matrigel and the filter, were fixed in methanol for 10 min at room temperature and stained with haematoxylin. The invaded areas were also measured by video micrometer (Figure 2
). From each well, the median values for spreading and invasion areas for three embryos were obtained. The assay was performed in triplicate chambers. The means of the three wells were defined as the value for each group for one experiment.
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Statistical analysis
The data were expressed as means ± SEM, and were analysed by repeated measures ANOVA, followed by Scheffé's F-test for post-hoc multiple comparisons. To assess the direct effect of HCG on embryo invasion, paired t-tests were used to compare the HCG treated group with the control group. Differences were regarded as significant at the 5% level.
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Results |
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Similarly to embryo spreading, the invasion areas of murine embryos beneath the filter were significantly enhanced by co-culture with PBMC derived from pregnant women (Figure 4). PBMC derived from non-pregnant women also promoted murine embryo invasion, but this effect was significantly lower than in that from pregnant women. These cells are shown in Figure 5
.
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Discussion |
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The promoting effect of PBMC derived from women in early pregnancy was significantly greater than that of PBMC obtained from non-pregnant women, indicating that there are some functional differences in PBMC between pregnant and non-pregnant women. Using human luteal cell culture from the corpus luteum of early pregnancy, similar functional alterations of PBMC to assist embryo implantation have been observed (Hashii et al., 1998). PBMC obtained from pregnant women more effectively stimulated progesterone production by luteal cells, which is advantageous in that it maintains endometrial receptivity for the embryo. Based on this and several related findings, we proposed that PBMC in early pregnancy receive information on the presence of the embryo at the implantation site. They then transmit this information into the ovary via blood circulation and regulate the function of the corpus luteum during pregnancy to indirectly facilitate embryo implantation in cooperation with HCG (Fujiwara et al., 1993
; Hattori et al., 1995
; Hashii et al., 1998
). Since PBMC from pregnant women were demonstrated to promote embryo invasion, it is also suggested that PBMC directly effect embryo outgrowth in the endometrium. This leads us to the concept that PBMC play an important role in establishing embryo implantation by indirectly regulating ovarian function and by directly promoting embryo invasion.
The next item for consideration is how the effects of PBMC on embryo invasion are enhanced. It is theoretically reasonable that PBMC are activated by the embryo at the implantation site. If so, what factors from the embryo serve as stimulators? At the implantation site, HCG is well known to be secreted from the embryo into the maternal blood and is transmitted to the ovary via blood circulation to support the function of the corpus luteum during pregnancy. As an embryonal signal, we therefore examined the effects of HCG on PBMC function. After PBMC were incubated with rHCG for 2 days, embryo invasion assays were performed under co-culture with rHCG-treated PBMC. The spreading and invasion areas of murine embryos were significantly increased in the co-culture with rHCG-treated PBMC compared with those with non-treated PBMC. These findings suggest that the promoting effect of PBMC on embryo invasion is enhanced by an important embryonal signal, namely HCG. Although the effect of HCG on the residual immune cells in the endometrium was not examined in this study, it is also possible that HCG secreted by the embryo can activate endometrial immune cells to support its own invasion. A recent study reported that HCG directly stimulated the invasion of human cytotrophoblastic JEG-3 cells in vitro (Zygmunt et al., 1998). On the contrary, the spreading and invasion of embryos were not affected by HCG in the absence of PBMC in this study, showing that HCG has little direct effect on murine embryo outgrowth. This discrepancy may be because there is no production of chorionic gonadotrophin at the implantation site in mice.
Recently, attention has been focused on the patients who fail to achieve successful implantation in spite of repeated intrauterine transfers of morphologically good embryos (Edwards, 1995). We have previously proposed that local administration of autologous PBMC into the endometrium is a possible approach for patients suffering from implantation failure (Takabatake et al., 1997b
; Fujita et al., 1998
). However, the effects of patients' PBMC on embryo implantation are estimated to be slight since the patients are not pregnant. In this regard, this study provides important evidence that HCG is a potent candidate for enhancing the promoting effect of patients' PBMC in vitro for clinical application. Lymphocytes from pregnant women were shown to express HCG receptor genes (Lin et al., 1995
). In addition, HCG was reported to modulate cytokine production by PBMC (Schäfer et al., 1992
). Further investigation should be performed to clarify what factors are produced from PBMC when pregnant and stimulated by HCG.
In conclusion, this study has demonstrated that PBMC promoted murine embryo invasion. This effect is prominent in PBMC derived from women in the early stage of pregnancy and was enhanced by HCG. These findings suggest a positive feedback loop in which PBMC in the implantation site is activated by HCG that is secreted from the embryo, and these PBMC then facilitate embryo implantation. In addition, results from this study raise the possibility that HCG activated patients' PBMC might be used for therapy in patients suffering from implantation failure.
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Acknowledgements |
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Notes |
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References |
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Submitted on April 27, 2001; accepted on August 21, 2001.