Premila Paiva

Models for Study of Human Embryo Implantation: Choice of Cell Lines?

Abstract Implantation failure and inadequate placental development are important contributors to infertility, recurrent miscarriage, and other pregnancy-related problems in women. Better understanding of these processes is hampered by the difficulty in obtaining human tissue from which primary cells can be prepared and by the very limited access worldwide to human blastocysts for experimentation. Therefore, the use of appropriate cell lines, particularly for functional studies of implantation and placentation, is imperative. While a number of cell lines for both endometrium and trophoblast have been developed and are widely used, it is difficult for researchers to decide which of these are most appropriate for studies of particular functions. This brief review summarizes the known phenotypes of the most widely used cell lines and indicates which might be the most appropriate for individual studies.

Local regulation of implantation at the human fetal-maternal interface

Embryo implantation and formation of a functional placenta are complex processes that require a plethora of regulatory molecules. In recent years, many of these mediators have been identified, often from studies in experimental animals. Furthermore, their expression patterns at the embryo-maternal interface in women have been characterized and provide clues to their potential actions. What has been missing in most cases is any experimental demonstration of their function. Proteases, cytokines and chemokines are among the molecules identified at the embryo-maternal interface. Functional studies of the protease, proprotein convertase (PC)6, the gp130 cytokines, leukemia inhibitory factor (LIF) and interleukin (IL)11 and the chemokines, CX3CL1 and CCL14 demonstrate potential actions within the uterine cavity. These actions include: enhancing blastocyst development, modifying adhesive properties of the blastocyst and the uterine epithelial surface, and providing chemotactic guidance to the blastocyst. As implantation proceeds, PC6 and IL-11 also act to drive decidualization. The products (proteases, chemokines and cytokines) produced by these decidual cells provide a unique environment. This is important for both directing and restraining trophoblast invasion and for leukocyte trafficking into the decidua until the placenta is fully established.

Analysis of Fertility-Related Soluble Mediators in Human Uterine Fluid Identifies VEGF as a Key Regulator of Embryo Implantation

Embryo implantation requires synchronized dialogue between the receptive endometrium and activated blastocyst via locally produced soluble mediators. During the midsecretory (MS) phase of the menstrual cycle, increased glandular secretion into the uterine lumen contains important mediators that modulate the endometrium and support the conceptus during implantation. This study aimed first to identify the growth factor and cytokine profile of human uterine fluid from fertile women during the midproliferative (MP; nonreceptive) and MS (receptive) phases of the cycle, and from women with unexplained infertility during the MS phase. The second aim was to determine important functions of endometrial secretions for embryo implantation. Analysis of uterine fluid using quantitative Luminex assays revealed the presence of over 30 cytokines and growth factors, of which eight [platelet-derived growth factor-AA, TNF-B, soluble IL-2 receptor-A, Fms-like tyrosine kinase 3 ligand, soluble CD40 ligand, IL-7, interferon-A2, and chemokine (C-X-C motif) ligand 1-3] were previously unknown in human uterine fluid. Comparison of the fertile MP, MS, and infertile MS cohorts revealed vascular endothelial growth factor (VEGF) levels are significantly reduced in uterine fluid during the MS phase in women with unexplained infertility compared with fertile women. Functional studies demonstrated that culturing mouse embryos with either MS-phase uterine fluid from fertile women or recombinant human VEGF significantly enhanced blastocyst outgrowth. Furthermore, treatment of human endometrial epithelial cells with uterine fluid or recombinant human VEGF-A significantly increased endometrial epithelial cell adhesion. Taken together, our data support the concept that endometrial secretions, including VEGF, play important roles during implantation. Identifying the soluble mediators in human uterine fluid and their actions during implantation provides insight into interactions essential for establishing pregnancy, fertility markers, and infertility treatment options.

Human chorionic gonadotrophin regulates FGF2 and other cytokines produced by human endometrial epithelial cells, providing a mechanism for enhancing endometrial receptivity

BACKGROUND Preimplantation cross-talk between a functional blastocyst and the endometrium is critical for successful blastocyst implantation. This interaction is mediated in part by endometrial cytokines/growth factors secreted by glandular epithelium into the uterine cavity. Recent evidence suggests that blastocyst-derived hCG may influence the endometrial milieu in conception cycles thereby enhancing receptivity and implantation success. This study investigated the effect of hCG on the secretory profile of a select cohort of 44 cytokines/growth factors from primary human endometrial epithelial cells (hEECs). These factors included those with both known and unknown roles during receptivity and implantation. The expression of one previously unknown hCG-regulated factor, fibroblast growth factor 2 (FGF2), in human endometrium and its effects on hEEC function were further examined. METHODS hEECs isolated from endometrial biopsies collected from fertile cycling women (n = 15) were treated ± recombinant hCG (0.2-20 IU/ml) for 48 h and conditioned media was quantitatively analysed using Luminex™ multiplex technology. FGF2 was further investigated by immunohistochemistry, western blot and cell-adhesion assays. RESULTS Of 44 cytokines/growth factors examined, 39 were produced by hEECs with a distinct profile. hCG (2 IU/ml) significantly increased the production of six factors, including those with known roles in receptivity and trophoblast function (interleukin-11), blastocyst migration and adhesion (CXCL10), blastocyst development (granulocyte macrophage colony-stimulating factor) and one unknown with respect to receptivity and implantation (FGF2). Up-regulation of known hCG-regulated proteins, vascular endothelial growth factor and leukaemia inhibitory factor, validated this study. Immunoreactive epithelial FGF2 increased across the menstrual cycle, being highest in secretory and first trimester pregnancy endometrium in vivo. FGF2 (100 ng/ml) stimulated phosphorylation of ERK1/2 in hEEC with no effect on ERK1/2 abundance and stimulated hEEC adhesion to fibronectin and collagen IV (components of blastocyst/trophectoderm extracellular matrix). CONCLUSIONS These findings clearly support roles for hCG and FGF2 in the blastocyst-endometrial cross-talk important for endometrial receptivity and blastocyst implantation.

Leukemia inhibitory factor and interleukin-11: Critical regulators in the establishment of pregnancy

Blastocyst implantation into a receptive endometrium is critical to the establishment of pregnancy and is tightly regulated by factors within the blastocyst-endometrial micro-environment. Leukemia inhibitory factor (LIF) and interleukin-11 (IL11) have key roles during implantation. Female mice with a null mutation in the LIF or IL11RA gene are infertile due to a complete failure of implantation or a defective differentiation/decidualization response to the implanting blastocyst, respectively. LIF and IL11 deficiency during pregnancy is associated with infertility and miscarriage in women. Numerous cell populations at the maternal-fetal interface are regulated by LIF/IL11 including the endometrial epithelium, decidualizing stroma, placental trophoblasts and leukocytes. This review focuses on the roles of LIF/IL11 during early pregnancy and highlights their potential as contraceptive targets and therapeutic agents for infertility.

Review: LIF and IL11 in trophoblast-endometrial interactions during the establishment of pregnancy.

Blastocyst implantation into the endometrium is critical for the establishment of pregnancy and is tightly regulated by factors within the blastocyst-endometrial micro-environment. Implantation is a continuum involving blastocyst adhesion to the endometrial epithelium followed by trophoblast penetration of the epithelium. The trophoblast proliferates and invades through the endometrium, with a subpopulation acting to remodel the spiral arteries. Trophoblast-endometrial interactions in humans involve carefully orchestrated temporal and spatial alterations in factors that are critical for pregnancy success. Emerging evidence suggests important roles for locally produced cytokines including interleukin 11 and leukemia inhibitory factor in the various stages of implantation. This review focuses on the role of these cytokines in trophoblast-endometrial interactions during the establishment of human pregnancy.

Measurement of mRNA Transcripts of Very High Placental Expression in Maternal Blood as Biomarkers of Preeclampsia

CONTEXT mRNA of placental origin in maternal blood shows potential as a clinical biomarker of obstetric diseases such as preeclampsia (PE). We hypothesized that mRNA transcripts very highly expressed in the placenta relative to other tissues will be differentially expressed in PE and be useful as mRNA biomarkers in maternal blood. OBJECTIVE Our objective was to identify a panel of genes highly expressed in the placenta and compare their expression in placenta and maternal whole blood from PE vs. control pregnancies. SETTING Placental tissue and maternal whole blood specimens were obtained from normotensive controls (n = 15) and pregnancies complicated by severe preterm PE (n = 21). INTERVENTION mRNA expression was evaluated by quantitative real-time RT-PCR. RESULTS We identified 20 genes exhibiting highest to fourth highest expression in the placenta relative to all other tissues. All genes were detectable in placenta. Nine of the 20 genes were detectable in maternal whole blood. Four of the nine genes detectable in blood (i.e. PLAC3, PLAC4, CRH, and ERVWE1) were significantly increased in both maternal blood and placenta from PE pregnancies. The remaining five genes detectable in maternal blood were unchanged in both blood and placenta from PE pregnancies. Thus, there was complete correlation of gene expression between maternal blood and placenta. CONCLUSIONS Circulating mRNA coding genes of high placental expression show strong correlation with transcript levels in preeclamptic placenta. Such transcripts may be promising candidates to screen as mRNA biomarkers of PE in maternal whole blood.

An evaluation of dose equivalence between synchrotron microbeam radiation therapy and conventional broadbeam radiation using clonogenic and cell impedance assays

Background High-dose synchrotron microbeam radiation therapy (MRT) has shown the potential to deliver improved outcomes over conventional broadbeam (BB) radiation therapy. To implement synchrotron MRT clinically for cancer treatment, it is necessary to undertake dose equivalence studies to identify MRT doses that give similar outcomes to BB treatments. Aim To develop an in vitro approach to determine biological dose equivalence between MRT and BB using two different cell-based assays. Methods The acute response of tumour and normal cell lines (EMT6.5, 4T1.2, NMuMG, EMT6.5ch, 4T1ch5, SaOS-2) to MRT (50–560 Gy) and BB (1.5–10 Gy) irradiation was investigated using clonogenic and real time cell impedance sensing (RT-CIS)/xCELLigence assays. MRT was performed using a lattice of 25 or 50 µm-wide planar, polychromatic kilovoltage X-ray microbeams with 200 µm peak separation. BB irradiations were performed using a Co60 teletherapy unit or a synchrotron radiation source. BB doses that would generate biological responses similar to MRT were calculated by data interpolation and verified by clonogenic and RT-CIS assays. Results For a given cell line, MRT equivalent BB doses identified by RT-CIS/xCELLigence were similar to those identified by clonogenic assays. Dose equivalence between MRT and BB were verified in vitro in two cell lines; EMT6.5ch and SaOS-2 by clonogenic assays and RT-CIS/xCELLigence. We found for example, that BB doses of 3.4±0.1 Gy and 4.40±0.04 Gy were radiobiologically equivalent to a peak, microbeam dose of 112 Gy using clonogenic and RT-CIS assays respectively on EMT6.5ch cells. Conclusion Our data provides the first determination of biological dose equivalence between BB and MRT modalities for different cell lines and identifies RT-CIS/xCELLigence assays as a suitable substitute for clonogenic assays. These results will be useful for the safe selection of MRT doses for future veterinary and clinical trials.

In vitro study of genes and molecular pathways differentially regulated by synchrotron microbeam radiotherapy.

The aim of this study was to identify genes and molecular pathways differentially regulated by synchrotron-generated microbeam radiotherapy (MRT) versus conventional broadbeam radiotherapy (CRT) in vitro using cultured EMT6.5 cells. We hypothesized (based on previous findings) that gene expression and molecular pathway changes after MRT are different from those seen after CRT. We found that at 24 h postirradiation, MRT exerts a broader regulatory effect on multiple pathways than CRT. MRT regulated those pathways involved in gene transcription, translation initiation, macromolecule metabolism, oxidoreductase activity and signaling transduction in a different manner compared to CRT. We also found that MRT/CRT alone, or when combined with inflammatory factor lipopolysaccharide, upregulated expression of Ccl2, Ccl5 or Csf2, which are involved in host immune cell recruitment. Our findings demonstrated differences in the molecular pathway for MRT versus CRT in the cultured tumor cells, and were consistent with the idea that radiation plays a role in recruiting tumor-associated immune cells to the tumor. Our results also suggest that a combination of MRT/CRT with a treatment targeting CCL2 or CSF2 could repress the tumor-associated immune cell recruitment, delay tumor growth and/or metastasis and yield better tumor control than radiation alone.

Eosinophil-associated gene pathways but not eosinophil numbers are differentially regulated between synchrotron microbeam radiation treatment and synchrotron broad-beam treatment by 48 hours postirradiation

Synchrotron microbeam radiation treatment (MRT) is a preclinical radiotherapy technique with considerable clinical promise, although some of the underlying radiobiology of MRT is still not well understood. In recently reported studies, it has been suggested that MRT elicits a different tumor immune profile compared to broad-beam treatment (BB). The aim of this study was to investigate the effects of synchrotron MRT and BB on eosinophil-associated gene pathways and eosinophil numbers within and around the tumor in the acute stage, 48 h postirradiation. Balb/C mice were inoculated with EMT6.5 mouse mammary tumors and irradiated with microbeam radiation (112 and 560 Gy) and broad-beam radiation (5 and 9 Gy) at equivalent doses determined from a previous in vitro study. After tumors were collected 24 and 48 h postirradiation, RNA was extracted and quantitative PCR performed to assess eosinophil-associated gene expression. Immunohistochemistry was performed to detect two known markers of eosinophils: eosinophil-associated ribonucleases (EARs) and eosinophil major basic protein (MBP). We identified five genes associated with eosinophil function and recruitment (Ear11, Ccl24, Ccl6, Ccl9 and Ccl11) and all of them, except Ccl11, were differentially regulated in synchrotron microbeam-irradiated tumors compared to broad-beam-irradiated tumors. However, immunohistochemical localization demonstrated no significant differences in the number of EAR- and MBP-positive eosinophils infiltrating the primary tumor after MRT compared to BB. In conclusion, our work demonstrates that the effects of MRT on eosinophil-related gene pathways are different from broad-beam radiation treatment at doses previously demonstrated to be equivalent in an in vitro study. However, a comparison of the microenvironments of tumors, which received MRT and BB, 48 h after exposure showed no difference between them with respect to eosinophil accumulation. These findings contribute to our understanding of the role of differential effects of MRT on the tumor immune response.