High Frequency of Imprinted Methylation Errors in Human Preimplantation Embryos.

Assisted reproductive technologies (ARTs) represent the best chance for infertile couples to conceive, although increased risks for morbidities exist, including imprinting disorders. This increased risk could arise from ARTs disrupting genomic imprints during gametogenesis or preimplantation. The few studies examining ART effects on genomic imprinting primarily assessed poor quality human embryos. Here, we examined day 3 and blastocyst stage, good to high quality, donated human embryos for imprinted SNRPN, KCNQ1OT1 and H19 methylation. Seventy-six percent day 3 embryos and 50% blastocysts exhibited perturbed imprinted methylation, demonstrating that extended culture did not pose greater risk for imprinting errors than short culture. Comparison of embryos with normal and abnormal methylation didn't reveal any confounding factors. Notably, two embryos from male factor infertility patients using donor sperm harboured aberrant methylation, suggesting errors in these embryos cannot be explained by infertility alone. Overall, these results indicate that ART human preimplantation embryos possess a high frequency of imprinted methylation errors.

Identification of WNT/beta-CATENIN signaling pathway components in human cumulus cells.

Signaling via the conserved WNT/beta-CATENIN pathway controls diverse developmental processes. To explore its potential role in the ovary, we investigated the expression of WNTs, frizzled (FZD) receptors and other pathway components in human cumulus cells obtained from oocytes collected for in vitro fertilization. Proteins were detected in cultured cells using immunofluorescence microscopy. Protein-protein interactions were analyzed by means of immunoprecipitation. WNT2, FZD2, FZD3 and FZD9 were identified but WNT1, WNT4 and FZD4 were not detected. WNT2 is co-expressed with FZD2, FZD3 and FZD9. Co-immunoprecipitation using WNT2 antibody demonstrated that WNT2 interacts with both FZD3 and FZD9, but only FZD9 antibody precipitated WNT2. We also identified DVL (disheveled), AXIN, GSK-3beta (glycogen synthase kinase-3beta) and beta-CATENIN. beta-CATENIN is concentrated in the plasma membranes. DVL co-localizes with FZD9 and AXIN in the membranes, but GSK-3beta has little co-localization with AXIN and beta-CATENIN. Interestingly, beta-CATENIN is highly co-localized with FZD9 and AXIN. CDH1 (E-cadherin) was also detected in the plasma membranes and cytoplasm, co-localized with beta-CATENIN, and CDH1 antibody precipitated beta-CATENIN. The results suggest that WNT2 could act through its receptor FZD9 to regulate the beta-CATENIN pathway in cumulus cells, recruiting beta-CATENIN into plasma membranes and promoting the formation of adherens junctions involving CDH1.

Periovulatory increases in tissue homing potential of circulating CD56(bright) cells are associated with fertile menstrual cycles.

CD56(bright) lymphocytes appear in the uterus 3-5 d after ovulation coincident with the onset of stromal cell decidualization. Although the source of these uterine immune cells is not defined, a subset of blood CD56(bright) cells exhibits enhanced capacity to adhere to decidual vascular endothelium during the periovulatory period of menstrual cycles. In this study, the effects of early pregnancy on the adhesive capacity of CD56(bright) cells to bind uterine substrates were examined in a time-course study of 18 infertile women undergoing natural cycles before transfer of frozen/thawed embryos and 18 infertile women undergoing controlled ovarian stimulation. There were three pregnancies in the natural cycle group and seven in the hormone-stimulated cohort. Hormone levels, and number and quality of transferred embryos were similar between pregnant and nonpregnant cycles. However, the adhesive function of CD56(bright) cells increased before ovulation in hormone-treated women who became pregnant and before embryo transfer in naturally cycling women who became pregnant. This pattern of incremental adhesion, which was less frequently observed in unsuccessful cycles, suggests a role for NK cells in implantation. These results support the idea that temporal control of NK cell homing to the uterine microenvironment is a prerequisite to pregnancy.