Crosstalk Between Trophoblast and Macrophage at the Maternal-Fetal Interface: Current Status and Future Perspectives.

The immune tolerance microenvironment is crucial for the establishment and maintenance of pregnancy at the maternal-fetal interface. The maternal-fetal interface is a complex system containing various cells, including lymphocytes, decidual stromal cells, and trophoblasts. Macrophages are the second-largest leukocytes at the maternal-fetal interface, which has been demonstrated to play essential roles in remodeling spiral arteries, maintaining maternal-fetal immune tolerance, and regulating trophoblast's biological behaviors. Many researchers, including us, have conducted a series of studies on the crosstalk between macrophages and trophoblasts at the maternal-fetal interface: on the one hand, macrophages can affect the invasion and migration of trophoblasts; on the other hand, trophoblasts can regulate macrophage polarization and influence the state of the maternal-fetal immune microenvironment. In this review, we systemically introduce the functions of macrophages and trophoblasts and the cell-cell interaction between them for the establishment and maintenance of pregnancy. Advances in this area will further accelerate the basic research and clinical translation of reproductive medicine.

Recognized trophoblast-like cells conversion from human embryonic stem cells by BMP4 based on convolutional neural network.

The use of models of stem cell differentiation to trophoblastic cells provides an effective perspective for understanding the early molecular events in the establishment and maintenance of human pregnancy. In combination with the newly developed deep learning technology, the automated identification of this process can greatly accelerate the contribution to relevant knowledge. Based on the transfer learning technique, we used a convolutional neural network to distinguish the microscopic images of Embryonic stem cells (ESCs) from differentiated trophoblast -like cells (TBL). To tackle the problem of insufficient training data, the strategies of data augmentation were used. The results showed that the convolutional neural network could successfully recognize trophoblast cells and stem cells automatically, but could not distinguish TBL from the immortalized trophoblast cell lines in vitro (JEG-3 and HTR8-SVneo). We compare the recognition effect of the commonly used convolutional neural network, including DenseNet, VGG16, VGG19, InceptionV3, and Xception. This study extends the deep learning technique to trophoblast cell phenotype classification and paves the way for automatic bright-field microscopic image analysis of trophoblast cells in the future.

Intermediate trophoblast--A distinctive, unique and often unrecognized population of trophoblastic cells.

The trophoblast forms an outer layer of the blastocyst in the developing placenta and fetal membrane chorion. It is composed of different types of cells. Two main cell types are cytotrophoblasts and syncytiotrophoblasts. The third type of trophoblastic cells, often "forgotten" in most of histological and embryological textbooks, is morphologically and functionally between the first and second one, therefore, it is called the intermediate trophoblast. There is no mention of it in the internationally accepted Terminologia Embryologica. This term is not universally used by pathologists as some of them prefer the name extravillous trophoblast. This review provides an overview of morphology, localization, function and immunohistochemistry of different types of intermediate trophoblast cells. An indisputable reason for categorizing these cells as a distinct group is the fact that they are a source of various forms of gestational trophoblastic disease.

Ets2 is necessary in trophoblast for normal embryonic anteroposterior axis development.

Although the trophoblast is necessary for the growth, viability and patterning of the mammalian embryo, understanding of its patterning role is still rudimentary. Expression of the transcription factor Ets2 is restricted to the trophoblast in early postimplantation stages and Ets2 mutants have been previously shown to have defects in trophoblast development. We show here that Ets2 is necessary in the trophoblast for fundamental aspects of anteroposterior (AP) epiblast axis initiation, including mesoderm initiation at the primitive streak, establishment of posterior character in the epiblast and appropriate spatial restriction of the anterior visceral endoderm (AVE). Most homozygous Ets2 mutants also show highly reduced development of the trophoblast with an absence of extraembryonic ectoderm (EXE) markers. Embryos in which the EXE has been physically removed before culture in vitro phenocopy the patterning defects of Ets2 mutants. These defects cannot be rescued by providing Ets2 mutants with wild-type epiblast in tetraploid aggregations. Thus, EXE-derived signals are necessary for normal embryonic patterning. Ets2 is likely to be required in the EXE downstream of epiblast signals, such as Fgf, and, in turn, helps to regulate signals from the EXE that signal back to the epiblast to promote proper primitive streak and AVE development. This study provides new insights about the genetic and cellular basis of the patterning role and development of the early trophoblast.

Differences in apoptotic susceptibility of cytotrophoblasts and syncytiotrophoblasts in normal pregnancy to those complicated with preeclampsia and intrauterine growth restriction.

Placental apoptosis is increased in vivo in preeclampsia (PE) and intrauterine growth restriction (IUGR). The cause and pathological implications of this phenomenon are unknown. This study considers the apoptotic susceptibility of villous trophoblasts from normal, PE, and IUGR pregnancies. Cultured cytotrophoblasts (CTs) and an in vitro model of syncytialization were used. CTs were isolated from term placentas of 12 normal, 12 PE, and 12 IUGR pregnancies. Apoptosis was determined by terminal dUTP nick-end labeling (TUNEL), Annexin V binding, and ADP:ATP ratios. Cells were stimulated with tumor necrosis factor-alpha/interferon-gamma or reduced oxygen (<5 KPa). For CTs, ADP:ATP <1 correlates with Annexin V binding. For normal pregnancy, tumor necrosis factor-alpha and depleted oxygen significantly increased TUNEL, Annexin V binding and ADP:ATP in CTs and syncytiotrophoblasts (STs). Spontaneous apoptosis was similar between groups for both cell types. After stimulation, TUNEL and Annexin V binding of CTs were significantly raised in PE and IUGR as compared with normal pregnancy. After oxygen reduction, ADP:ATP in CTs and STs were significantly elevated in IUGR. TUNEL was also increased in STs in PE after oxygen depletion and was significantly raised in STs from IUGR pregnancies after stimulation with both agonists. This is the first description of enhanced apoptosis in isolated villous trophoblasts in PE and IUGR. These intrinsic differences may represent an important factor in the pathophysiology of these conditions.

Genome multiplication of extravillous trophoblast cells in human placenta in the course of differentiation and invasion into endometrium and myometrium. I. Dynamics of polyploidization.

Polyploidization of the extravillous trophoblast (EVT) cells at different stages of differentiation and invasion into the uterine wall in human placenta has been studied. An increase in the ploidy level of EVT cells in the course of their differentiation within cell columns (CC) was shown. Stem cells were mainly diploid (86.2%); incidence of polyploid nuclei of highly proliferative cells of the proximal part of CC increased progressively. In the distal part of CC, where EVT cells did not divide mitotically, polyploid cells prevailed, with 58.0 and 3.5% nuclei being 4c and 8c, respectively. The highest percentage of polyploid cells was found in the population of EVT cells attached directly to the surface of the decidualized endometrium: percentage of tetraploid cells turned out to be 74.7% and the share of octaploid nuclei rose up to 4.9%; however, there appeared a few (0.3%) 16c cells. The majority of EVT cells invading the decidualized endometrium were polyploid, the share of octaploid and hexadecaploid cells rose up to 9.7 and 1.4%, respectively. On the other hand, the percentage of diploid cells also increased up to 29.2% as compared to EVT cells attached to decidua (20.0%). The same tendency proved to be even stronger in myometrium: the share of diploid EVT cells increased up to 46.0%, a prominent amount of tetraploid (45.1%) and highly polyploid (8c and 16c) cells retained in the EVT cell population (7.4 and 1.1%, respectively). Immunohistochemical staining of Ki-67 protein (MIB1), which labels cells held in the cell cycle, showed a high incidence of MIB1-positive stem cells (93.7%) and the EVT cells of the proximal part of CC (85.5%) characterized by high mitotic activity. A lower MIB1-positivity (43.2%) was found in the distal part of CC, whereas invasive EVT cells showed no MIB1-labeling. The presence of MIB1-positive nuclei in the distal part of CCs in the absence of mitoses, taken together with data on polyploidization of these cells, indicates their switch to the endoreduplication cycle. As a whole, the data obtained evidence that differentiation of EVT cells of the invasive pathway is accompanied by polyploidization. However, in a population of trophoblast cells capable of most profound invasion (up to myometrium), the proportion of diploid cells rose. These results suggest that the human cytotrophoblast invasion into the uterine wall requires an optimum, not the highest, ploidy level, whereas highly polyploid cells may form a subpopulation at the border between the maternal and fetal parts of placenta.

First trimester human endovascular trophoblast cells express both HLA-C and HLA-G.

PROBLEM: In human pregnancies, trophoblasts, in contrast to placental connective tissue and the fetus itself, come into direct contact with the maternal allorecognizing system at special sites. Villous syncytiotrophoblasts washed around by maternal blood lack HLA class I proteins, whereas extravillous trophoblasts, which deeply invade maternal uterine tissues, express high amounts of HLA-G and also HLA-C, the latter to a lesser degree, however. A subpopulation of extravillous trophoblasts, the endovascular trophoblast, enters maternal spiral artery lumen and, like syncytiotrophoblast, comes into direct contact with maternal blood. Less is known about HLA class I distribution on this endovascular trophoblast subpopulation. METHOD OF STUDY: A comparative immununohistochemical analysis was done on decidual cryo-sections containing trophoblast-invaded spiral arteries using different anti-HLA class I monoclonal antibodies (mAbs) and a peroxidase-labeled streptavidinbiotin detection system. RESULTS: MAbs W6/32 (anti-HLA-A, -B, -C, -G), HCA2 (anti-HLA-A, -G) G233 and 87G (both anti-HLA-G) resulted in strong positivity on endovascular trophoblasts. L31 (anti-HLA-C) and HC10 (anti-HLA-B, -C) revealed clear positivity, whereas TU149 (anti-HLA-B, -C, some -A) produced a heterogeneous staining pattern, faintly positive on some endovascular trophoblastic cells and negative on others. MAb LA45 (anti-HLA-A, -B) did not bind to any endovascular trophoblast, neither did BFL.1 (anti-HLA-G) nor 16G1 (anti-HLA-G, soluble). CONCLUSION: This study shows that trophoblastic cells belonging to the endovascular subpopulation express considerable amounts of HLA-G and slightly less HLA-C.