O-233 Cell-cell interactions within germ cell nests reveal the mechanism of primordial follicle formation in humans

Study question

How interactions between human fetal female germ cells (hFGCs) and pre-granulosa cells (pre-GCs) affect the hFGCs transition from ovarian cord to primordial follicles (PFs).

Summary answer

Progressive engulfment of hFGCs by pre-GCs and establishment of cell-cell junctions and cell-cell adhesions between hFGCs and pre-GCs leads to PF formation in humans.

What is known already

In mice, development of FGCs is synchronized due to formation of cysts. Cysts comprise of sister FGCs that remain connected via intercellular bridges until germ cell nest breakdown is initiated and PFs are formed. In contrast, hFGCs differentiate asynchronously. In second trimester human ovaries, mitotic, RA-responsive, meiotic and oogonia hFGCs are present in designated parts of the ovary that corresponds to their differentiation stage. Meiotic hFGCs enter prophase I that is divided into 4 substages: leptotene, zygotene, pachytene, diplotene/dictyate. hFGCs in diplotene are ready to form a PF with pre-GCs and become dormant.

Study design, size, duration

We collected in total 17 second trimester human fetal ovaries between 14 and 22 weeks of gestation from elective abortions. We have analyzed cellular structures of hFGC and pre-GCs by transmission electron microscopy and investigated different cell adhesion and cell junction proteins by immunostaining.

Participants/materials, setting, methods

Materials: human fetal ovaries between 14 and 22 weeks of gestation.

Methods: characterization of tissue morphology, immunofluorescence staining, whole mount staining, confocal microscopy, super-resolution microscopy, transmission electron microscopy (TEM), cell counting

Main results and the role of chance

Meiotic hFGCs formed germ cell cysts consisting of multiple sister hFGCs connected by intercellular bridges. Furthermore, we discovered that a subset of hFGCs formed syncytia containing several nuclei (2–4 nuclei). Syncytium formation was caused by cytokinesis failure when an in intercellular bridge failed to be formed. In addition, in some cases hFGC syncytia were connected to other syncytia or mono-nucleated hFGCs by an intercellular bridges. Those multinucleated syncytia did not display signs of apoptosis or morphological abnormalities. Investigation of physical interactions between hFGCs and pre-GCs revealed that as hFGCs enter prophase I, pre-GCs (FOXL2+, VIM+, CDH1+) form membrane protrusions (MPs) and progressively engulf them. First, CDH1+ and VIM+ domains within a pre-GC are mixed, but as engulfment progresses two distinct domains are formed. MP formation is possible due to mesenchymal-epithelial hybrid state and active Hippo pathway in pre-GCs. Inside the cords, hFGCs highly express CDH2, while CDH2 is lowly expressed in pre-GCs. At diplotene, hFGCs (TP63+) downregulate CDH2 and upregulate CDH1. Expression of CDH1 in both diplotene hFGC and pre-GCs causes increase of cell-cell adhesion and enables PF formation. In addition, progressive formation of tight junctions (TJP1+) and cellular interdigitations between pre-GCs and meiotic hFGCs reinforce PF structure.

Limitations, reasons for caution

Due to technical limitations and lack of in vitro culture protocols that support meiotic hFGCs development and survival as well as human PF formation in vitro, we cannot experimentally validate roles of cadherins and other cell junction and cell adhesion proteins in PF formation

Wider implications of the findings

In depth understanding of PF formation process in terms of physical interactions between hFGCs and pre-GCs will be crucial to design in vitro conditions that will support PF formation and our findings will be key to achieve assembling of PFs in artificial human oocytes (gametes) created from pluripotent stem cells.

Trial registration number

not applicable

Effect of small molecule supplements during in vitro culture of mouse zygotes and parthenogenetic embryos on hypoblast formation and stem cell derivation

BACKGROUND

Small molecule inhibitors are organic components that modulate signalling pathways and have the ability to change the differentiation state of cells. They have been used to increase the efficiency of induced pluripotent stem cell generation and to support stem cell derivation and culture. In this study, we aimed to evaluate the effects of small molecules on the development of mouse zygotes and parthenogenetic embryos.

METHODS AND RESULTS

Three inhibitors (SC-1, PD0325901 and BIO) were added to the culture medium from the 2-cell stage onwards. We have observed that addition of an inhibitor of the fibroblast growth factor (FGF) pathway (SC-1 or PD0325901) compromises the segregation of hypoblast from the inner cell mass (ICM). Given no difference was observed in size of the ICM, but more epiblast cells were found in these embryos, we can conclude that this is caused by redirection of all ICM cells to the epiblast. We also determined the consequences of reduced hypoblast and increased epiblast formation on stem cell derivation efficiency. No significant difference was found between derivation rates from treated embryos as compared to controls. However, only under 2i + ROCKi conditions, stem cells could be derived with an efficiency of more than 90%. Addition of BIO, an activator of the WNT pathway, did not have any effects on hypoblast development or stem cell derivation.

CONCLUSION

We have demonstrated that FGF signalling is crucial for hypoblast generation and small molecules can be efficiently used to inhibit this process both in zygotes and parthenogenetic embryos.