Human blastocysts are comprised of the first three cell lineages of the embryo: trophectoderm, epiblast and primitive endoderm, all of which are essential for early development and organ formation. However, due to ethical concerns and restricted access to human blastocysts, a comprehensive understanding of early human embryogenesis is still lacking. To bridge this knowledge gap, a reliable model system that recapitulates early stages of human embryogenesis is needed. Here we developed a three-dimensional (3D), two-step induction protocol for generating blastocyst-like structures (EPS-blastoids) from human extended pluripotent stem (EPS) cells. Morphological and single-cell transcriptomic analyses revealed that EPS-blastoids contain key cell lineages and are transcriptionally similar to human blastocysts. Furthermore, EPS-blastoids are similar with human embryos that were cultured for 8 or 10 days in vitro, in terms of embryonic structures, cell lineages and transcriptomic profiles. In conclusion, we developed a scalable system to mimic human blastocyst development, which can potentially facilitate the study of early implantation failure that induced by developmental defects at early stage.
Human embryogenesis begins with a fertilized egg and then undergoes cell divisions, lineage segregations, and morphogenic rearrangements lay the foundation for blastocyst formation. Following activation of the embryonic genome and the beginning of compaction and polarization, blastomeres undergo lineage segregation and morphogenetic rearrangements to form a ball-shaped structure termed the blastocyst1,2,3. Blastocysts contain specialized cell types, namely epiblast (EPI), primitive endoderm (PE), and trophectoderm (TE)4,5,6. In recent years, “multi-omic” technologies have enabled researchers to chart the gene-transcription and chromatin-modification landscapes of these cell types, providing valuable information regarding human embryogenesis7,8,9,10. However, the supply of human embryos is extremely limited due to ethical and technical limitations, thereby precluding a precise mechanistic understanding of early human embryogenesis. To systematically interrogate the early human development, a robust in vitro model of human embryogenesis is urgently needed.
Using human embryonic stem cells (hESCs), researchers have been working toward modeling embryogenesis in a dish. Previous studies have reported that hESCs cultured in three-dimensional (3D) soft-gel or a microfluidics device can form embryonic sac-like structures that mimic the early postimplantation human EPI and amnion development11,12,13. Recently, 3D human gastrulating embryo-like structures (gastruloids) were generated by subjecting hESCs to a pulse of Wnt agonist, allowing modeling of the spatiotemporal organization of the three germ layers during gastrulation14. However, all these models use only EPI-derived hESCs and lack cells resembling the TE and PE. Therefore, they can not fully recapitulate the lineage interactions that characterize human embryonic development. In addition, recent studies suggested that hESCs are of postimplantation EPI origin and represent the primed pluripotency state5,15. Therefore, hESCs may not be suitable for modeling preimplantation development.
Recently, researchers have attempted to generate human stem cells resembling those in the preimplantation embryo (i.e., exhibiting naive pluripotency). These efforts revealed a continuum of pluripotency in the form of human naive stem cells or extended pluripotency stem cells (EPS cells)16,17. With these cells, it became possible to test whether they can self-organize into preimplantation embryo-like structures. This interest was further stimulated by recent success in generating mouse blastocyst-like structures, blastoids18,19,20. Mouse EPS cell aggregates recapitulate several morphogenic hallmarks of preimplantation embryogenesis and differentiate into both embryonic and extra-embryonic lineages, thus forming blastoids that share many features of the blastocyst. Recently, three groups have reported the reprogramming of fibroblasts into in vitro three-dimensional models of the human blastocyst, and the generation of blastocyst-like structures in vitro from naive human pluripotent stem cells21,22,23. However, given the significant differences between mice and humans, it is unclear whether human EPS cells can also generate blastoids in vitro to mimic human embryogenesis from preimplantation to postimplantation stages.
In this study, we developed a 3D, two-step differentiation protocol for generating human blastocyst-like structures from human EPS cells, named EPS-blastoids. Human EPS-blastoids partially resembled human blastocyst in terms of morphology, specific markers for the three cell lineages, and global transcriptome signatures at single-cell resolution. Importantly, further in vitro culturing of these human EPS-blastoids resulted in the emergence of structures similar to those observed in early postimplantation embryos.
A 3D two-step differentiation method for generating human blastoid
By using an established protocol16, we converted human induced pluripotent stem cells (iPSCs) into EPS cells16. Then we attempted to generate human blastoids from these EPS cells using a modified protocol for generating mouse blastoids18. However, EPS cell aggregates treated with induction media containing BMP4 generally failed to form a cavity-containing structure after 5 days of induction (Supplementary Fig. S1a). A few aggregates appeared to contain a small cavity, but they were enclosed by a membrane instead of TE-like cells and did not have the typical morphology and size of a blastocyst. Immunofluorescence labeling showed that the majority of these solid structures expressed the EPI marker OCT4 and the PE marker GATA6, while small fraction (~10% of day 6 aggregates) also expressed the TE markers CK8 and GATA2/3 (about 30%–50% of TE cells in each aggregate), albeit partially (Supplementary Fig. S1b, c). These results indicate that at least a small number of human EPS cells were capable of differentiating into the TE lineage with BMP4 induction using the modified mouse blastoids protocol18.
We then attempted to pretreat human EPS cells with BMP4 to generate TE-like cells. First, gene expression was analyzed via real-time quantitative PCR (qPCR) during a time-course of BMP4 induction to optimize human EPS cell differentiation conditions. Between day 0 and day 5 of BMP4 stimulation, EPI-specific genes were gradually downregulated as TE-specific genes were upregulated (Supplementary Fig. S1d). Interestingly, genes characteristic of mid- and late-TE were activated by BMP4 induction, with most TE-specific genes reaching 1.5–10-fold induction by day 3 (30- and 500-fold for WNT7 and GATA3, respectively) (Supplementary Fig. S1e). Higher levels of induction were observed on day 5 of BMP4 treatment. TE-like cells exhibited morphological changes by 2 days of BMP4 induction, with cells becoming flattened and enlarged (Supplementary Fig. S1f). Immunostaining revealed more GATA2/3-, CK7-, CK8-, and TFAP2C-positive cells on day 3 compared with day 1 or 2 (Supplementary Fig. S1g, h). As day 3 marks the onset of significant gene expression and morphological changes, we decided to use TE-like cells subjected to 3 days of BMP4 pretreatment for subsequent experiments.
Given the importance of TE-like cells for making blastoids structures, we further characterized these EPS-derived TE-like cells and compared them to TE derivatives of pluripotent stem cells (PSCs). We performed RNA sequence (RNA-seq) analysis of EPS-derived TE-like cells following BMP4 or BAP (BMP4, A83-01, and PD0325901) treatments and compared the gene expression data with published data of TE-like cells derived from human naive PSCs treated with BAP or with A83-01 and PD 0325901 (PDA83)24,25. Human EPS cells and naive PSCs clustered together in principal component analysis (PCA), while TE-like cells formed a separate cluster. EPS cells and naive PSCs shared a similar differentiation trajectory when subjected to TE-inducing conditions (Supplementary Fig. S2a). qPCR analysis showed that genes associated with TE, such as GATA3, TFAP2C, GATA2, DAB2, and KRT18, which was also observed in BMP4-treated naive PSCs, were significantly upregulated in EPS cells treated with BMP4 for 3 days (Supplementary Fig. S2b). Moreover, hierarchical clustering of gene expression showed that while EPS-derived TE-like cells had a comparable (hEPS-BMP/BAP vs PXGL_PDA83) or better (hEPS-BMP/BAP vs iNPSC_BAP) upregulation of TE marker genes when compared to naive PSCs TE derivatives, they extinguished the pluripotency program more completely (Supplementary Fig. S2c). On the other hand, EPS cells expressed high levels of pluripotency genes associated with the preimplantation naive state (e.g., KLF4 and NANOG) but not the postimplantation primed state (e.g., ZIC2), and efficiently downregulated pluripotency genes upon BMP4 treatment (Supplementary Fig. S2b, d). These data suggest exposure of EPS cells to BMP4 for 3 days enabled reliable TE fate transition.
To generate human blastoids, we first pretreated human EPS cells with BMP4 to generated TE-like cells, and then mixed human EPS cells with these TE-like cells at a ratio of 1:4–1:5 (Fig. 1a). After 24 h, these loosely connected cells formed small aggregates, which grew and formed structures with a small cavity by day 4. By days 5–6, blastocyst-like structures were apparent (Fig. 1b), with about 1.9% exhibiting typical blastocyst morphology (Fig. 1c). Morphologically these human blastoids were similar to natural human blastocysts (Fig. 1d, e) in terms of average diameter, but blastoids seemed to have more total cells and fewer cells in the inner cell mass (ICM) (Fig. 1f–h).
Human EPS-blastoids contain cells of the three lineages of blastocysts
Mixing TE-like cells and EPS cells resulted in cell aggregation and the formation of blastocyst-like structures (EPS-blastoids) on day 5. To investigate whether EPS-blastoid formation recapitulated key cellular processes, we monitored cellular dynamics of blastoids during days 2 and 3. We found that the cell-adhesion protein, E-cadherin (E-cad), localized to cell–cell junctions, indicating cell–cell interactions and communications within EPS aggregates26 (Supplementary Fig. S3a). Ki-67 labeling showed the proliferation of EPS-blastoids on days 5 and 6 (Supplementary Fig. S3b).
We sought to determine whether blastoids contained the three cell lineages of the blastocyst, namely EPI, PE and TE, as all three are necessary for an embryo to develop beyond implantation. Immunofluorescence analysis of day 4 blastoids revealed extremely low levels of OCT4 in the outer cell layer (TE cells), with highest levels localized to EPI cells in the interior of the ICM. Cells surrounding these OCT4-positive cells expressed the PE marker, GATA6, as seen in natural early blastocysts27 (Supplementary Fig. S4a). Immunofluorescence analysis of EPS-blastoids during days 5 and 6 revealed that OCT4-positive cells localized exclusively to the ICM-like compartment (Fig. 2a, e), whereas cells in the outer layer expressed the TE-specific transcription factors, GATA2 and GATA3 (Fig. 2c, d). The outer layer of cells also expressed the trophoblast (TrB)-specific cytokeratin, KRT8 (CK8), indicative of TE specification (Fig. 2e). The PE marker, GATA6, localized to cells adjacent to the OCT4-positive cells (not those within the outer layer of the blastoids) (Fig. 2b, f). This pattern of localization is similar to that seen in human blastocysts (Fig. 2g). In some blastoids, the positive signal of OCT4 and GATA6 can be detected in TE (Fig. 2e, f), indicating the incomplete programming of TE lineage from EPSCs.
We then calculated the percentage of CK8-positive or OCT4-positive cells in day 6 EPS-blastoids (n = 172). These analyses revealed a smaller fraction of OCT4-positive cells than that in human blastocysts, whereas the fraction of CK8-positive cells was reminiscent of human blastocysts. On average, there were ~15% and 80% of cells expressed OCT4 and CK8 in one blastoid, respectively (Supplementary Fig. S3c, d). Of these, 53.5% exhibited the correct pattern of ICM- (OCT4+) and TE-like (CK8+) localization, 36.6% exhibited only correct TE-like pattern (CK8+), 5.8% had only the ICM-like lineage, and 4.1% exhibited mislocalization of ICM- and TE- like cells (Fig. 2h). With further development of early blastocysts, the ICM divides into two lineages: EPI and PE. We examined whether blastoids could develop into late blastocyst-like structures composed of three lineages (EPI, PE and TE). Of 131 blastoids on day 6, about 8% cells of one blastoid were positive for GATA6 expression on average (Supplementary Fig. S3e). Of these, 26% showed PE-like lineage (GATA6+, in a stochastic manner) (Fig. 2i), 21% expressed all three lineage markers (Fig. 2j). Moreover, around 80% of the blastoids expressed OCT4, CK8, or GATA6 (Supplementary Fig. S3f–h). Using this induction system, a large proportion of EPS cells failed to form blastoids, although they expressed markers indicative of the EPI, PE and TE lineages. They instead retained features of day 4 aggregates (Supplementary Fig. S4a). In some abnormal day 6 aggregates, OCT4, SOX2 or GATA6 localized improperly to TE cells (Supplementary Fig. S4b–e) instead of the ICM. In summary, these results demonstrated that EPS-blastoids recapitulated the segregation of TE and ICM cell lineages, and that these blastoid structures possessed the three lineages typical of a blastocyst, however, the incomplete programmed EPSCs can be still detected in some blastoids.
To confirm the existence of EPI and TE lineages in EPS-blastoids, we attempted to derive ESCs, PSCs, and trophoblast stem cells (TSCs) from day 6 EPS-blastoids. We were able to establish 3 PSC lines from 6 EPS-blastoids, and 4 TSC lines from 10 EPS-blastoids using the culture condition reported previously28,29 (Supplementary Fig. S5a, e). PSCs and TSCs were morphologically similar to those derived from blastocysts (Supplementary Fig. S5b, f). PSC colonies expressed the pluripotency markers OCT4, SOX2, SSEA4, and TRA-1-60 (Supplementary Fig. S5c), whereas TSC colonies expressed the TE-specific markers GATA3, CK7, and TFAP2C (Supplementary Fig. S5g). Further, PSCs derived from EPS-blastoids showed the trilineage differential potential (Supplementary Fig. S5d). TSCs derived from blastoids can generate syncytiotrophoblasts (STBs) and extravillous cytotrophoblasts (EVTs) (Supplementary Fig. S5h–j). The PCA indicated that PSCs and TSCs derived from blastoids showed a closer transcriptional resemblance to the PSCs and TSCs lines25 (Supplementary Fig. S5K).
Single-cell transcriptome analysis of human blastoids
We performed single-cell RNA-sequencing (scRNA-seq) analysis of 200 day 6 human blastoids. After quality control and filtering, 10,933 single cells were further analyzed using the bioinformatic suite Seurat. Uniform manifold approximation and projection (UMAP) clustering analysis showed that cells from human blastoids could be divided into 12 clusters (Supplementary Fig. S6a). Base on the expression of marker genes (Supplementary Fig. S6a), we characterized two clusters as EPI/ICM, two clusters as PE, and two clusters as TE. The remaining six clusters seemed to express both ICM and TE markers and could each represent an intermediate cell type (Fig. 3a, b). In addition, we performed unsupervised clustering analysis and confirmed that the top genes specific for each lineage were consistent with the UMAP clustering results. The EPI/ICM cluster expressed OCT4 (POU5F1), NANOG, and SOX2, the PE cluster expressed FN1, COL3A1, and GATA6, and the TE cluster expressed GATA2 and GATA3 (Fig. 3b, d; Supplementary Fig. S6c). UMAP analysis showed blastoid EPI-, TE-, and PE-like clusters together with EPI, TE, and PE cells of blastoids from two recent published study (Supplementary Fig. S6d).
To reveal similarities and differences between EPS-blastoids and natural blastocysts, we compared our scRNA-seq data from day 6 EPS-blastoids with a dataset acquired from human blastocysts7. Comparisons of our results with data derived from E5–E7 blastocysts7 revealed 40, 16, and 37 genes that overlapped with those in EPS-blastoid EPI, PE, and TE clusters, respectively (Supplementary Fig. S6b Table S1). UMAP analysis revealed that cells from EPI-, TE-, and PE- like clusters mostly overlapped with EPI, TE, and PE counterparts from blastocysts (Fig. 3c). The expression of overlapped differentially expressed genes (DEGs) between three lineages was shown in heat map (Fig. 3e; Supplementary Table S1). Overall, our scRNA-seq analysis revealed similarities between the transcriptome landscape of EPS-blastoids and early blastocysts and confirmed that, by day 6, human blastoids contained the three cell lineages found in blastocysts.
Human EPS-blastoids can develop postimplantation embryonic structures
To test whether human EPS-blastoids could undergo postimplantation morphogenesis, we kept culturing day 6 blastoids within 2–4 days (hereafter referred to as day 8 and day 10 embryonic structures) using a previously established in vitro culture (IVC) system, which needed matrigel and modified IVC1/2 medium to mimic blastocyst implantation30,31. On day 8, GATA6-positive cells encircled the OCT4-positive cells (Fig. 4a). On day 10, the localization patterns for OCT4 and GATA6 resembled those on day 8, except for an increased number of cells within the day 10 embryonic structures (Fig. 4b). Moreover, GATA3 positive cells were distributed around the postimplantation structure (Fig. 4a, b).
We then performed scRNA-seq analysis using day 8 (40) and day 10 (20) human embryonic structures. After quality control and filtering, 11,634 single cells from day 8 and 7872 single cells from day 10 were further analyzed. The human placenta consists of three major TrB subpopulations: CTBs, STBs, and EVTs. UMAP analysis by Seurat revealed that the primary clusters could be identified as EPI, PE, TrB (CTBs and STBs) on day 8 (Fig. 4c, Supplementary Fig. S7b), and EPI, PE, TrB (CTBs and STBs) on day 10 (Fig. 4d, Supplementary Fig. S8b). This is based on the expression of 16 representative marker genes respectively (Supplementary Fig. S6a, S7a).
To reveal similarities and differences between EPS embryonic structures and natural blastocysts subjected to IVC, we compared our results of EPS embryonic structures from days 8 and 10 with data acquired from 7 to 14 d.p.f IVC embryos32,33. A total of 155, 263, and 78 genes, specific for our ICM, PE, and TB clusters (day 8) overlapped with Xiang’s analyses of 7–14 d.p.f IVC embryos (Supplementary S7c; Table S1). Similarly, comparison of day 10 embryonic structures and 7–14 d.p.f. IVC embryos revealed 175, 157, and 40 genes that overlapped with our EPI, PE, and TB clusters (Supplementary Fig. S8c; Table S1), respectively. UMAP analysis revealed a concordance between cells of embryonic structures on days 8 and 10 and 7–14 d.p.f IVC embryos (Fig. 4e, Supplementary Fig. S8d). Moreover, heat map showed that our EPS embryonic structures (days 8 and 10) and 7–14 d.p.f IVC embryos had a similar transcriptional profile (Fig. 4f). In conclusion, embryo-like structures cultured from EPS-blastoids in vitro (days 8 or 10) resembled natural human embryos in terms of their single-cell transcriptome landscape in a certain degree, performing their potential in modeling human early postimplantation development.
Mouse EPS cells can be induced to form blastocyst-like structures (blastoids)18,19. Because of the significant differences between mouse and human developmental processes, it is thought that the generation of human blastoids may be more challenging. Indeed, applying the modified mouse culture system to human EPS cells failed to generate blastoids. To overcome this obstacle, we developed a 3D, two-step induction system for generating blastoids from human EPS cells. In our two-step induction system, we first exposed EPS cells to BMP4 for 3 days to induce TE-like cells formation. These TE-like cells were then mixed with EPS cells to generate EPS-blastoids. We found that TE-like cells expressed early-, mid-, and late-TE cell markers, which enhanced their subsequent developmental potential. Human EPS-blastoids were similar to human blastocysts of the same stage based on both morphology and cell lineage analysis. The latter conclusion was based on immunofluorescence and scRNA-seq analyses. The efficiency of EPS-blastoids was lower than seen for mouse blastoids (1.9% vs 15% in the human and mouse systems, respectively). One potential reason for this difference is the difficulty in maintaining stemness and pluripotency of human EPS cells in our differentiation system. The human EPS cells were difficult to maintain as dome-shaped colonies during the cultivation and contained differentiated cells that could disturb blastoids formation. Other reasons include differences between human and mouse early embryonic development and differences between the mouse and human embryo culture system. Culture medium is an important component for inducing blastoids. The efficiency of the culture system for human embryos is not as robust as the mouse system. Up to 90% of mouse embryos can develop to blastocysts in vitro, whereas only 50% of human embryos reach the blastocyst stage. The efficiency of PE lineage derivation is relatively lower than EPI and TE lineage. There are some possible reasons: First, there is no mature PE derivation protocol now, which is hard to induced EPS cells to classical PE cells; Second, the PE lineage grows mature slower than EPI and TE lineage. The PE markers often are shown express in TE cells, which is difficult to identify the right PE pattern and calculate the percentage of right phenotype. Also, the comparisons of our scRNA-seq data with previous data suggested that the human two-step blastoid differentiation system must be further optimized to achieve a potential model system for studying the human blastocyst. Moreover, it is few transcriptome data-sets available for human blastocysts and blastoids using the similar system of scRNA-seq, therefore, further detailed analysis are required from early developmental stages to postimplantation stages.
Our human EPS-blastoids recapitulated to a great extent the 3D-architecture of human blastocysts and exhibited all three developmental lineages. Functionally, we could derive both PSCs and TSCs from human EPS-blastoids. More importantly, they gave rise to postimplantation embryonic structures. These observations suggested that hESC-blastoids manifest at least some functionalities of the natural human blastocyst. The ability of hEPS-blastoid to generate several types of mature TrBs like those present in the human placenta offers great promise for studying placenta disorders in the future.
In summary, we have established an in vitro system for generating human blastoids that accurately recapitulate the development of a human blastocyst. We note that during the preparation of this manuscript three studies21,22,23 reported successful generation human blastoids from human iPSCs and naive PSCs, respectively. The human blastoid models provide an alternative and potentially high-throughput platform for exploring the mechanisms of human blastocyst development and stem cell differentiation during preimplantation and postimplantation stages.
Materials and methods
Human samples and ethics statement
Human skin fibroblasts were isolated from chest of a female aborted fetus that were obtained with informed written consent and approval by the Third Affiliated Hospital of Guangzhou Medical University. The generation of iPSCs with donated human fibroblasts was approved by the Ethics of Third Affiliated Hospital of Guangzhou Medical University. Human blastocysts produced from in vitro fertilization for clinical purposes were got with informed written consent and approval by the Third Affiliated Hospital of Guangzhou Medical University. All procedures were approved by the Institutional Review Board of the Third Affiliated Hospital of Guangzhou Medical University (2020027), and Peking University Third Hospital (S2020022).
Generation of human EPS cells from human PSCs
The human PSCs and EPS cells culturing conditions were as follows: 37 °C, 5% CO2 and saturated humidity. Human iPSCs were generated using the electroporation (4D-Nucleofector System, Lonza) of fibroblasts with episomal vectors, including pCXLE-hOCT3/4-shp53-F, pCXLE-hSK, and pCXLE-hUL as previously reported34. The derived iPSCs were cultured on mitomycin C-treated MEF feeder cells in human ESC medium. The human ESC medium consisted of DMEM/F12 (Thermo Fisher Scientific, 11330-032) supplemented with 20% Knockout Serum Replacement (Thermo Fisher Scientific, A3181502), 0.1 mM NEAA (nonessential amino acids, Thermo Fisher Scientific, 10828-028), 2 mM L-glutaMAX (Thermo Fisher Scientific, 35050-061), 0.1 mM β-mercaptoethanol (Thermo Fisher Scientific, 21985-023), 1% penicillin/streptomycin (Thermo Fisher Scientific, 15140-122), and 10 ng/ml recombinant bFGF (Thermo Fisher Scientific, PHG0261). Human iPSCs were converted to EPS cells referred to protocol described previously16. Human iPSCs were digested into single cells by TrypLE Express Enzyme (Thermo Fisher Scientific, 12604021) or Accutase (Stem Cell Technologies, #07920) and seeded to the plate with fresh ICR MEF cells. After 12 h seeding, the human ESC medium was replaced with human N2B27-LCDM medium. N2B27 basal medium was prepared as following: 240 ml DMEM/F12 (Thermo Fisher Scientific, 11330-032), 240 ml Neurobasal (Thermo Fisher Scientific, 21103-049), 2.5 ml N2 supplement (Thermo Fisher Scientific, 17502-048), 5 ml B27 supplement (Thermo Fisher Scientific, 12587-010), 1% nonessential amino acids (Thermo Fisher Scientific, 11140-050), 1% L-glutaMAX (Thermo Fisher Scientific, 35050-061), 0.1 mM β-mercaptoethanol (Thermo Fisher Scientific, 21985-023), 1% penicillin/streptomycin (Thermo Fisher Scientific, 15140-122), 5% knockout serum replacement (KSR, Thermo Fisher Scientific, A3181502). Human N2B27-LCDM medium consisted of N2B27 basal medium supplemented with 10 ng/ml human LIF (R&D Systems, 7734), 3 μM CHIR99021 (Tocris, 4423), 2 μM (S)-(+)-Dimethindene maleate (Tocris, 1425), and 2 μM minocycline hydrochloride (Selleckchem, S4226), 1 μM IWR endo-1 (Selleckchem, S7086), and 2 μM Y-27632 (Selleckchem, S1049). The N2B27-LCDM medium was changed every day. Dome-shaped colonies emerged after 3–6 days. Then the cells were dissociated and passaged to the next generation.
In vitro 3D generation of human EPS-blastoids
The blastoids culturing conditions were as follows: 37 °C, 5% O2, 5% CO2 and saturated humidity. Human EPS cells were differentiated with BMP4 for 3–4 days. BMP4 differentiation medium was composed of N2B27 basal medium, supplemented with 25 ng/ml BMP4 (R&D Systems, 314-BP-010), 2 μM Y-27632 (Selleckchem, S1049). On day 0, the cultured EPS cells were digested into single cells by TrypLE Express (Thermo Fisher Scientific), and the MEF cells were removed by pasting twice on 0.5% gelatin (Sigma) for 15–20 min each time. The EPS cells were collected, centrifuged, and seeded into plate pretreated with Matrigel in BMP4 differentiation medium. After 3 days of differentiation, cells were dissociated into single cells with Tryple Express. Mix the BMP4-treated cells (1.0 × 105 cells) and EPS cells (2.0 × 104 cells) together following 5:1 ratio to total 1.2 × 105 cells per well with 0.5 ml culture medium, and then seeded into one well of 24-well aggreWell400 culture plate pretreated with anti-adherence rinsing solution (Stem Cell Technologies, #07010) following instruction. The culture medium was slightly changed without disturbing aggregates in the V-shape bottom every day and aggregates were collected on day 6. The culture medium of human EPS-blastoids is composed of EPS medium and IVC1 medium in a ratio of 1.5:1 (v/v). IVC1 culture medium is composed of Advanced DMEM/F12 (Thermo Fisher Scientific, 12634-010), 20% Heat-inactivated FBS (Thermo Fisher Scientific, 30044333), 2 mM L-glutaMAX (Thermo Fisher Scientific, 35050-061), 0.5% penicillin/streptomycin (Thermo Fisher Scientific, 15140-122), 1% ITS-X (Thermo Fisher Scientific, 51500-056), 1% sodium pyruvate (Thermo Fisher Scientific), 8 nM β-estradiol (Sigma-Aldrich, E8875), 200 ng/mL progesterone (Sigma-Aldrich, P0130) and 25 μM N-acetyl-L-cysteine (Sigma-Aldrich, A7250).
In vitro culture of EPS-blastoids for 8 and 10 days
The method of embryo extended cultured in vitro refers to the previous studies30,31. The blastoids were collected on day 6, and transferred to the eight-well plate (treated with Matrigel 30 min in advance), and cultured with IVC1 for 2 days. On day 8, observe whether blastoids were adherent to the bottle of the dish or not, and replace the culture medium with IVC2 for further culture if the blastoids were adherent to the well till to day 10. The composition of IVC1 medium is the same as describe in the “In vitro 3D generation of human EPS-blastoids”, IVC2 culture medium is composed of Advanced DMEM/F12, 30% Knockout serum, 2 mM L-glutaMAX, 0.5% penicillin/streptomycin, 1% ITS-X, 1% sodium pyruvate, 8 nM β-estradiol, 200 ng/mL progesterone, 2 μM Y27632 and 25 μM N-Acetyl-L-cysteine.
Derivation of stem cells from human blastoids
To derive ES cells28, individual EPS-blastoid was transferred onto a MEF layer in a 96-well plate and cultured with human ESC culture medium (see above). After 2–3 days, EPS-blastoid attached to the MEF and outgrew. Then outgrowth was digested by TrypLE Express and transfered into a new MEF feeder layer. Colony was picked, digested, and seeded onto a new MEF plate for ESC derivation. To derive TS cells29, EPS-blastoid was seeded in a 48-well plate coated with 5 μg/ml Collagen IV (Coring, 354233) at 37 °C overnight and cultured in human TS medium (DMEM/F12 supplemented with β-mercaptoethanol (Thermo Fisher Scientific), 0.2% FBS (Thermo Fisher Scientific), 0.5% penicillin/streptomycin, 0.3% BSA, 1% ITS-X supplement, 1.5 μg/mL L-ascorbic acid (Sigma, A4403), 50 ng/mL EGF (Sigma, E5036), 2 μM CHIR99021 (Tocris, 4423), 0.5 μM A83-01 (Selleckchem, S7692), 1 μM SB431542 (Selleckchem, S1067), 0.8 mM VPA (Selleckchem, S1168) and 5 μM Y27632 (Sellleckchem). When cells reached 70% confluence, cells were digested by TrypLE Express Enzyme and transferred into a new Collagen IV-coated 96-well plate at a ratio of 1:4.
For embryoid body (EB) formation, primed PSCs at 70% confluency were gently picked using a glass needle and cultured in DMEM/F-12, GlutaMAX supplemented with 20% KSR, 1% nonessential amino acids and 55 μM β-mercaptoethanol and 2 ng/ml bFGF (Thermo Fisher Scientific) for EB formation on ultra-low-binding attachment plates (Corning), with medium replacement every other day. On day 7, the trilineage differentiation assay of primed PSCs was performed on the matrigel-coated four-well plate in EB induction media for 4–5 days.
Differentiation of TSCs into STBs and EVTs was performed and modified as previously described29. For the differentiation of TSCs into STBs, TSCs were seeded at a density of 4 × 104 cells per well onto a four-well plate pre-coated with 2.5 μg/ml collagen IV (Sigma) and cultured in 500 μl ST differentiation medium (DMEM/F-12, L-glutaMAX supplemented with 0.3% BSA (Sigma), 4% KSR, 1% ITS-X supplement, 0.1 mM β-mercaptoethanol, 0.5% penicillin/streptomycin, 2.5 μM Y27632 and 2 μM forskolin (Selleckchem, S2449)). Medium was replaced on day 3 of differentiation, and cells were fixed on day 6. For the differentiation of TSCs into EVTs, TSCs were seeded at a density of 4 × 104 cells per well onto a four-well plate pre-coated with 1 μg/ml collagen IV (Sigma) and cultured in 500 μl EVTs differentiation medium (DMEM/F-12, L-glutaMAX supplemented with 0.3% BSA (Sigma, B2064), 4% KSR, 1% ITS-X supplement, 0.1 mM β-mercaptoethanol, 0.5% penicillin/streptomycin, 2.5 μM Y27632 (Selleckchem), 100 ng/ml hNRG1 (Cell Signaling Technology, #26941), 7.5 μM A83-01 (Selleckchem) and 2% Matrigel. On day 3 of differentiation, the medium was replaced with EVT differentiation medium without hNRG1, and Matrigel (Corning) was added to a final concentration of 0.5%. On day 6 of differentiation, EVTs differentiation medium was replaced without hNRG1 and KSR, and Matrigel was added to 0.5% final concentration. The cells were cultured for an additional 2 days before analyses were performed.
Generation of human naive PSCs from human PSCs
The cells culturing conditions were as follows: 37 °C, 5% O2, 5% CO2 and saturated humidity. PXGL naive PSCs were chemically converted from H1 ESC following a two-step conversion process as previously described. Initially, primed state PSCs in KSR/FGF were cultured for 3 days in cRM1 medium containing N2B27 basal medium, 10 ng/ml LIF, 1 μM PD0325901 (Selleckchem, S1036), and 1 mM VPA (valproic acid, Selleckchem, S1168). These cells where then propagated in PXGL naive PSCs medium containing 10 ng/ml LIF (R&D Systems, 7734), 1 μM PD0325901 (Selleckchem, S1036), 2 μM Gö6983 (Selleckchem, S2911), and 2 μM XAV939 (Selleckchem, S1180). In both conversion mediums, 10 μM Rock inhibitor Y-27632 (Selleckchem, S1049) was added to prevent cell death. Ten days after the start of the conversion process, domed-shape colonies appeared in culture. These domed-shape colonies (PXGL naive PSCs) were either picked manually or plated on 0.5% gelatin (Sigma) for 50 min to remove differentiated cells, and PXGL naive PSCs were further passaged to achieve homogenous domed-shape colonies. For BMP4 induction of PXGL naive PSCs, it is same with BMP4-treated EPS cells. BMP4 differentiation medium was composed of N2B27 basal medium, supplemented with 25 ng/ml BMP4 (R&D Systems, 314-BP-010), 2 μM Y-27632 (Selleckchem, S1049). On day 0, the cultured naive PSCs were digested into single cells by TrypLE Express, and the MEF cells were removed by pasting twice on 0.5% gelatin (Sigma) for 15–20 min each time. The naive PSCs were collected and seeded into plate pretreated with Matrigel in BMP4 differentiation medium. After 3 days of differentiation, cells were dissociated into single cells with Tryple Express. PXGL naive PSCs and EPS-derived TE-like cells were analyzed using qPCR and immunofluorescence labeling.
The samples were fixed with 4% paraformaldehyde in phosphate-buffered saline (PBS) for 20 min at room temperature, washed three times with PBS, and permeabilized with 0.2% Triton X-100 in PBS for 15 min. After blocking with 5% BSA in PBS for 2 h at room temperature, samples were then incubated with primary antibody diluted in blocking buffer overnight at 4 °C. After primary antibody incubation, samples were washed three times with PBS containing 0.1% Tween20. Samples were washed three times with PBS containing 0.1% Tween20 and incubated with fluorescence-conjugated secondary antibodies diluted in blocking buffer at temperature for 2 h. Nuclei were stained with Hoechst 33342 (Sigma, 94403) at 1 μg/mL. Zeiss LSM 710 or 880 and Leica SP8 confocal microscopes were used for imaging. Images were processed by ZEN (Zeiss) and Fiji (ImageJ, V2.0.0) software. The primary antibodies and dilutions were following: mouse anti-OCT4 (Santa Cruz, sc5279, polyclonal, A0616, F2719, 1:200), rabbit anti-GATA6 (Cell Signaling Technology, 5851S, monoclonal, D61E4, 4, 1:1000), mouse anti-SOX2 (Abcam, ab171380, monoclonal, 20G5, GR32833, 1:200), rabbit anti-GATA2/3 (Abcam, ab182747, monoclonal, EPR17874, GR22065, 1:200), rabbit anti-CK8 (Abcam, ab53280, monoclonal, EP1628Y, 2, 1:200), mouse anti-E-cadherin (Abcam, ab1416, monoclonal, HECD-1, GR33004, 1:200), rabbit anti-TFAP2C (Cell Signaling Technology, 2320S, polyclonal, 1:200), rabbit anti-CK7 (Abcam, ab192077, monoclonal, EPR1619Y, GR325605, 1:200), mouse anti-CK7 (Invitrogen, monoclonal, OVTL12/30, MA106316, 1:200), rabbit anti-TP63 (Biotium, polyclonal, BNUB0375-100, 1:100), goat anti-CK18 (Santa Cruz, polyclonal, N-16, sc-31700, 1:100), mouse anti-GATA3 (R&D Systems, monoclonal, 634913, MAB6330, 1:100), goat anti-OCT4 (Santa Cruz, polyclonal, N-19, sc-8628, 1:100). The secondary antibodies were: Alexa Fluor 488 Goat anti-Rabbit IgG (H+L) (Thermo Fisher Scientific, A-11008), Alexa Fluor 555 Goat anti-Mouse IgG (H+L) (Cell Signaling Technology, 4409S), Alexa Fluor 647 Goat anti-Rabbit IgG (H+L) (Abcam, ab150083, GR3269213), Alexa Fluor 488 donkey anti-rabbit (H+L) (Thermo Fisher Scientific, A-21206), Alexa Fluor 568 donkey anti-mouse (H+L) (Thermo Fisher Scientific, A-10037), Alexa Fluor 647 donkey anti-goat (H+L) (Thermo Fisher Scientific, A-21447).
Real-time quantitative PCR
Total RNA was extracted using TRIzol (Invitrogen, 15596018). RNA (2 μg) was reverse-transcribed to cDNA template using RevertAid First Strand cDNA Synthesis Kit (Thermo Fisher Scientific, K1621). qPCR was analyzed in the Applied Biosystems QuantStudio 3. The changes of genes were calculated by the comparative ΔΔCt method or ΔCt method relative to GAPDH expression. All the experiments were performed in triplicates. The primers used in this study were listed in Supplementary Table S2.
hCG ELISA detection
The medium was collected from conditional medium of TSC-STBs. The hCG level in the medium was measured using a human CG beta (HCG beta) ELISA kit (R&D Systems, DY9034-05) according to the manufacturer’s instructions.
RNA-sequencing and analysis
TE-like cells derived of human EPS cells that were pretreated with BMP or BAP were sequenced using paired-end reads (PE150) on a NovaSeq following directional library preparation. All bulk RNA-seq samples from this study and previously published datasets were uploaded into the online RNA-seq analysis platform by Sequentia (A.I.R) for reads mapping and statistical analysis. NOI-seq analysis was performed and PCA plot was constructed.
Human EPS-blastoids were picked up by mouth pipette and washed with PBS containing 0.05% BSA. About day 6 EPS-blastoids (200), day 8 (40) and day 10 (20) human embryonic structures were collected for single-cell RNA-seq. Samples on day 6 were dissociated with enzyme mix composed of 0.5× Versene (Lonza, 17711E), 0.5× Accumax (STEMCELL Technologies, 07921) and 0.05× DNaseI (STEMCELL Technologies, 07900) at 37 °C for 30 min with agitation and terminated by 5% BSA in PBS. Samples on day 8 or 10 were dissociated with enzyme mix composed of 0.25% Trypsin (Thermo Fisher Scientific, 25200056), and 0.05× DNaseI (STEMCELL Technologies, 07900) at 37 °C for 15 min with agitation and terminated by 5% BSA in PBS. Dissociated cells were repeated pipetting and washed with PBS containing 0.05% BSA. Using single-cell 3' Library and Gel Bead Kit V3 (10× Genomics, 1000075), the cell suspension (700–1000 living cells per microliter determined by Count Star, about 10,000 dissociated cells each sample) were loaded onto the Chromium Single Cell B Chip (10× Genomics, 1000074) and processed in the Chromium single-cell controller (10× Genomics) to generate single-cell gel beads in the emulsion according to the manufacturer’s protocol. In short, single cells were suspended in PBS containing 0.04% BSA (700–1000 cells per ml). No more than 10,000 cells were added to each channel. Captured cells were lysed and the released RNA was barcoded through reverse transcription in individual GEMs35. Using a S1000TM Touch Thermal Cycler (Bio Rad) to reverse transcribe, the GEMs were programed at 53 °C for 45 min, followed 85 °C for 5 min, and hold at 4 °C. The cDNA was generated and then amplified, and the quality was assessed using the Agilent 4200. According to the manufacture’s instruction, Single-cell RNA-seq libraries were constructed using Single Cell 3’ Library and Gel Bead Kit V3. Finally, sequencing was performed on the Illumina Novaseq6000 sequencer with a sequencing depth of at least 60,000 reads per cell and 150 bp (PE150) paired-end reads (performed by Capital, Beijing and Novogene, Beijing).
Analysis of single-cell RNA-sequencing (scRNA-seq) data
The Cell Ranger software was obtained from 10× Genomics website: https://support.10xgenomics.com/single-cell-gene-expression/software/downloads/latest. Alignment, filtering, barcode counting, and UMI counting were performed with Cell Ranger count module to generate feature-barcode matrix and determine clusters. Dimensionality reduction was performed using PCA and the first ten principal components were used to generate clusters by K-means algorithm and graph-based algorithm, respectively. The other clustering method is Seurat 4.0.3 (R package). The R package Seurat 4.0.3 was used to analyze feature-barcode matrix as following steps: (1) Cells whose gene numbers were less than 100, unique features count over 60,000, and mitochondrial gene ratio was more than 20% according to quality control matrix plots, were regarded as abnormal and filtered out. (2) UMI counts were normalized with SCTransform function by default settings. A nonlinear dimensionality reduction was performed using PCA, clustered with resolution setting at 0.6, and visualized by TSNE and UMAP. (3) Differentially expressed genes (DEGs) in clusters were determined by the FindAllMarkers function (Seurat 4.0.3) using a minimum upregulation of 0.25 log-fold. DEGs between lineages with uncorrected P values were smaller than 0.01, and log-fold change was larger than 0.25 (log2FC > 0.25) in one group were regarded as DEGs. The GO terms of DEGs in biological process were enriched using DAVID. Heat map of top DEGs between clusters was performed with DoHeatmap (Seurat 4.0.3). Then the overlapped DEGs between blastoids and blastocysts were normalized and showed in heat map by DoHeatmap (Figs. 3, 4). The basic information of the scRNA-seq profiles were available in Supplementary Table S2.
Integrated scRNA-seq analysis
Previously published single-cell dataset from Petropoulos et al.7 was integrated with the day 6 blastoids dataset. Petropoulos’s 1529 cells were filtered for blastocyst cells, removing the pre-blastocyst stages to leave 1096 E5–E7 EPI, TE, and PE cells. Petropoulos’s data was processed using SCTransform. The dataset was integrated into the day 6 blastoids data after identifying integration genes (using FindIntegrationAnchors and IntegrateData) using 4000 anchor genes derived from the SCT assays. The integrated dataset of blastoids has 4000 integrated genes. UMAP were used for dimensionality reduction and FindClusters to identify clusters (resolution 0.8). Similarly, the published single-cell datasets from Xiang et al. (461 cells) and Zhou et al. (5911 cells)32,33 were integrated with the day 8 and day 10 blastoids datasets. Further, the published datasets from Yu et al. (4497 cells, D9 blastoids; 5i/L/A) and Liu et al. (7861 cells)21,22 were integrated with the day 6 blastoids and E5–E7 blastocysts datasets.
Statistical analyses were performed with GraphPad Prism 8 software, using unpaired two-tailed Student’s t-tests and one-way ANOVA. All the statistical tests performed are indicated in the figure legends. The data are presented as means ± SD, and P < 0.05 was regarded as significant differences. For cell numbers and gene expression, the significant differences between two samples were analyzed by GraphPad Prism 8 software.
scRNA-seq data have been deposited in the Gene Expression Omnibus (GEO) under accession number GSE158971 (scRNA-seq data website:). The scRNA-seq of human pre- and early postimplantation embryos (for Figs. 3, 4) are with GEO accession E-MTAB-39297 and GSE13644732. Bulk RNA-seq of BMP-TE and BAP-TE used in extended Fig. 2 from this study can be found as followings described. First replica of PXGL-naive and PXGL_PDA83 bulk RNA-seq data were used and can be accessed at (GEO: GSE166401). iNPSC (R27A04 and R27A04), iNPSC-BAP (R26C10 and R27G02), EPS-TSC (R27DO3, R27D02, GC317, and R27C12) and iNPSC-TSC (R27B11, R27B08, R27B01, R27A12, R27B10, and R27A11) can be accessed at (https://www.ebi.ac.uk/ena/browser/view/PRJEB34037).
Shahbazi, M. N. Mechanisms of human embryo development: from cell fate to tissue shape and back. Development 147, dev190629 (2020).
Rossant, J. & Tam, P. P. L. New insights into early human development: lessons for stem cell derivation and differentiation. Cell Stem Cell 20, 18–28 (2017).
Wamaitha, S. E. & Niakan, K. K. Human pre-gastrulation development. Curr. Top. Dev. Biol. 128, 295–338 (2018).
Niakan, K. K., Han, J., Pedersen, R. A., Simon, C. & Pera, R. A. Human pre-implantation embryo development. Devevelopment 139, 829–841 (2012).
Nakamura, T. et al. A developmental coordinate of pluripotency among mice, monkeys and humans. Nature 537, 57–62 (2016).
Cockburn, K. & Rossant, J. Making the blastocyst: lessons from the mouse. J. Clin. Invest. 120, 995–1003 (2010).
Petropoulos, S. et al. Single-cell RNA-Seq reveals lineage and x chromosome dynamics in human preimplantation embryos. Cell 165, 1012–1026 (2016).
Blakeley, P. et al. Defining the three cell lineages of the human blastocyst by single-cell RNA-seq. Development 142, 3613 (2015).
Harikumar, A. & Meshorer, E. Chromatin remodeling and bivalent histone modifications in embryonic stem cells. EMBO Rep. 16, 1609–1619 (2015).
Guo, H. et al. The DNA methylation landscape of human early embryos. Nature 511, 606–610 (2014).
Shao, Y. et al. A pluripotent stem cell-based model for post-implantation human amniotic sac development. Nat. Commun. 8, 208 (2017).
Zheng, Y. et al. Controlled modelling of human epiblast and amnion development using stem cells. Nature 573, 421–425 (2019).
Shao, Y. et al. Self-organized amniogenesis by human pluripotent stem cells in a biomimetic implantation-like niche. Nat. Mater. 16, 419–425 (2017).
Martyn, I., Kanno, T. Y., Ruzo, A., Siggia, E. D. & Brivanlou, A. H. Self-organization of a human organizer by combined Wnt and Nodal signalling. Nature 558, 132–135 (2018).
Nichols, J. & Smith, A. Naive and primed pluripotent states. cell stem cell 4, 487–492 (2009).
Yang, Y. et al. Derivation of pluripotent stem cells with in vivo embryonic and extraembryonic potency. Cell 169, 243–257 (2017). e225.
Gao, X. et al. Establishment of porcine and human expanded potential stem cells. Nat. Cell Biol. 21, 687–699 (2019).
Li, R. et al. Generation of Blastocyst-like structures from mouse embryonic and adult cell cultures. Cell 179, 687–702 (2019). e618.
Sozen, B. et al. Self-organization of mouse stem cells into an extended potential blastoid. Dev. Cell 51, 698–712 (2019). e698.
Rivron, N. C. et al. Blastocyst-like structures generated solely from stem cells. Nature 557, 106–111 (2018).
Liu, X. et al. Modelling human blastocysts by reprogramming fibroblasts into iBlastoids. Nature 591, 627–632 (2021).
Yu, L. et al. Blastocyst-like structures generated from human pluripotent stem cells. Nature 591, 620–626 (2021).
Yanagida, A. et al. Naive stem cell blastocyst model captures human embryo lineage segregation. Cell Stem Cell 28, 1016–1022 (2021). e4.
Guo, G. et al. Human naive epiblast cells possess unrestricted lineage potential. Cell Stem Cell 28, 1040–1056 (2021). e6.
Castel, G. et al. Induction of human trophoblast stem cells from somatic cells and pluripotent stem cells. Cell Rep. 33, 108419 (2020).
Alikani, M. Epithelial cadherin distribution in abnormal human pre-implantation embryos. Hum. Reprod. 20, 3369–3375 (2005).
Niakan, K. K. & Eggan, K. Analysis of human embryos from zygote to blastocyst reveals distinct gene expression patterns relative to the mouse. Dev. Biol. 375, 54–64 (2013).
Thomson, J. A. et al. Embryonic stem cell lines derived from human blastocysts. Science 282, 1145–1147 (1998).
Okae, H. et al. Derivation of human trophoblast stem cells. Cell Stem Cell 22, 50–63 (2018). e56.
Bedzhov, I., Leung, C. Y., Bialecka, M. & Zernicka-Goetz, M. In vitro culture of mouse blastocysts beyond the implantation stages. Nat. Protoc. 9, 2732–2739 (2014).
Deglincerti, A. et al. Self-organization of the in vitro attached human embryo. Nature 533, 251–254 (2016).
Xiang, L. et al. A developmental landscape of 3D-cultured human pre-gastrulation embryos. Nature 577, 537–542 (2020).
Zhou, F. et al. Reconstituting the transcriptome and DNA methylome landscapes of human implantation. Nature 572, 660–664 (2019).
Okita, K. et al. A more efficient method to generate integration-free human iPS cells. Nat. Methods 8, 409–412 (2011).
Zheng, G. X. et al. Massively parallel digital transcriptional profiling of single cells. Nat. Commun. 16, 14049 (2017).
This work was supported by the Strategic Priority Research Program of the Chinese Academy of Sciences (XDA16020700), the National Key R&D Program of China (2019YFA0110804, 2017YFA0105001, 2016YFC1000601, 2018YFA0801400, 2018YFC1003203), the National Natural Science Fundation of China (81925013, 81971381, 81771580, 81571400, 82071723, 81871162), Guangdong Basic and Applied Basic Research Foundation (2021B1515020069) and Outstanding Overseas Returnees Fund of the Peking University Third Hospital (BYSYLXHG2019002). Work in the Li laboratory was supported by KAUST Office of Sponsored Research (OSR), under award number BAS/1/1080-01. We thank the members of the Li lab, Jinna Xu, Baolei Yuan, Chongwei Bi, Xuan Zhou, Gerardo Ramos Mandujano, Khaled Alsayegh, Yingzi Zhang, Yeteng Tian, and KAUST Core Labs for their generous help in this research.
Conflict of interest
The authors declare no competing interests.
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Fan, Y., Min, Z., Alsolami, S. et al. Generation of human blastocyst-like structures from pluripotent stem cells. Cell Discov 7, 81 (2021). https://doi.org/10.1038/s41421-021-00316-8
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