Protocol to derive human trophoblast stem cells directly from primed pluripotent stem cells.

Human trophoblast stem cells (hTSCs) are useful for studying human placenta development and diseases, but primed human pluripotent stem cells (hPSCs) routinely cultured in most laboratories do not support hTSC derivation. Here, we present a protocol to derive hTSCs directly from primed hPSCs. This approach, containing two strategies either with or without bone morphogenetic protein 4 (BMP4), provides a simple and accessible tool for deriving hTSCs to study placenta development and disease modeling without ethical limitations or reprogramming process. For complete details on the use and execution of this protocol, please refer to Wei et al. (2021).

Efficient derivation of human trophoblast stem cells from primed pluripotent stem cells.

Human trophoblast stem cells (hTSCs) provide a valuable model to study placental development and function. While primary hTSCs have been derived from embryos/early placenta, and transdifferentiated hTSCs from naïve human pluripotent stem cells (hPSCs), the generation of hTSCs from primed PSCs is problematic. We report the successful generation of TSCs from primed hPSCs and show that BMP4 substantially enhances this process. TSCs derived from primed hPSCs are similar to blastocyst-derived hTSCs in terms of morphology, proliferation, differentiation potential, and gene expression. We define the chromatin accessibility dynamics and histone modifications (H3K4me3/H3K27me3) that specify hPSC-derived TSCs. Consistent with low density of H3K27me3 in primed hPSC-derived hTSCs, we show that knockout of H3K27 methyltransferases (EZH1/2) increases the efficiency of hTSC derivation from primed hPSCs. Efficient derivation of hTSCs from primed hPSCs provides a simple and powerful model to understand human trophoblast development, including the pathogenesis of trophoblast-related disorders, by generating disease-specific hTSCs.

Generation of two RNF2 homozygous knockout human embryonic stem cell lines by CRISPR/Cas9 system.

Human RNF2 (RING1B) gene is a critical epigenetic modification factor for embryonic development, pluripotency and differentiation of embryonic stem cells (ESCs). To further gain insights into the role of RNF2 in cell fate decisions of human ESCs, here we generated two RNF2 homozygous knockout human ESC lines by CRISPR/Cas9 genome editing technology. These cell lines maintained a normal karyotype and typical undifferentiated state in terms of morphology, pluripotent gene expression, and had differentiation potential in vivo. These cell lines provide good cell resources to explore the role of RNF2 gene in embryonic development and lineage differentiation in vitro.

Deciphering a distinct regulatory network of TEAD4, CDX2 and GATA3 in humans for trophoblast transition from embryonic stem cells.

The placenta is an essential organ for the fetus, but its regulatory mechanism for formation of functional trophoblast lineage remains elusive in humans. Although widely known in mice, TEAD4 and its downstream targets CDX2 and GATA3 have not been determined in human models. In this work, we used a human model of trophoblast transition from BAP (BMP4, A83-01 and PD173074)-treated human embryonic stem cells (hESCs) and performed multiple gain- and loss-of-function tests of TEAD4, CDX2 or GATA3 to study their roles during this process. Although hESCs with TEAD4 deletion maintain pluripotency, their trophoblast transition potentials are attenuated. This impaired trophoblast transition could be rescued by separately overexpressing TEAD4, CDX2 or GATA3. Furthermore, trophoblast transition from hESCs is also attenuated by knockout of CDX2 but remains unaffected with deletion of GATA3. However, CDX2-overexpressed hESCs maintain pluripotency, whereas overexpression of GATA3 in hESCs leads to spontaneous differentiation including trophoblast lineage. In brief, our findings using a human model of trophoblast transition from BAP-treated hESCs reveal transcription roles of TEAD4, CDX2 and GATA in humans that are different from those in mice. We hope that this evidence can aid in understanding the distinct transcriptional network regulating trophoblast development in humans.

Tuning FOXD3 expression dose-dependently balances human embryonic stem cells between pluripotency and meso-endoderm fates.

Forkhead box D3 (FOXD3) is a key transcription factor maintaining pluripotency in mouse embryonic stem cells (ESCs). Yet to date studies on its role in human ESCs are quite limited. In this study, we report that deletion of FOXD3 in human ESCs results in loss of pluripotency and spontaneous differentiation toward meso-endoderm. Ectopic overexpression of FOXD3 in hESCs leads to two different phenotypes: Human ESCs expressing high levels of FOXD3 undergo spontaneous meso-endoderm differentiation, whereas those with lower levels of FOXD3 maintain pluripotency. Next we deleted endogenous FOXD3 in the low ectopic expression model and find that addition of exogenous FOXD3 at a low level could rescue FOXD3-deficiency phenotype in hESCs. In summary, our findings suggest that FOXD3 dose-dependently regulates the balance of human ESCs between pluripotency and meso-endoderm fates, which adds to our understanding of the role of FOXD3 in humans.