Project description:Human embryo models hold great promise as surrogates for studying development and as platforms for medicine. However, existing models lack efficiency and fidelity in replicating post-implantation stages. Here we asked if STAT3 could reprogram pluripotent stem cells (PSCs) into all blastocyst fates and generate embryo models. Using a medium for enhanced STAT3 activity (SAM), PSCs rapidly reprogram into intermediates that specify all blastocyst fates: hypoblast, trophectoderm and naïve-pluripotent epiblast, within 60 hours. Strikingly, following dissociation of SAM-treated PSCs on 60 or 120 hours and subsequent 3D assembly, structures resembling post-implantation embryos develop within 4 days, with up to 52.41±8.92% efficiency. These exhibited a bilaminar disc-like structure, including epiblast and hypoblast discs, yolk-sac and amniotic cavities, mesenchyme tissue, chorionic cavity, and trophoblast. The STAT3-mediated embryo models (stEMs) also demonstrate unparalleled molecular alignment with the Carnegie Stage 6-7 embryo reference. Thus, stEMs offer state-of-the-art models for advancing our understanding of post-implantation human embryogenesis.

Project description:Human embryo models hold great promise as surrogates for studying development and as platforms for medicine. However, existing models lack efficiency and fidelity in replicating post-implantation stages. Here we asked if STAT3 could reprogram pluripotent stem cells (PSCs) into all blastocyst fates and generate embryo models. Using a medium for enhanced STAT3 activity (SAM), PSCs rapidly reprogram into intermediates that specify all blastocyst fates: hypoblast, trophectoderm and naïve-pluripotent epiblast, within 60 hours. Strikingly, following dissociation of SAM-treated PSCs on 60 or 120 hours and subsequent 3D assembly, structures resembling post-implantation embryos develop within 4 days, with up to 52.41±8.92% efficiency. These exhibited a bilaminar disc-like structure, including epiblast and hypoblast discs, yolk-sac and amniotic cavities, mesenchyme tissue, chorionic cavity, and trophoblast. The STAT3-mediated embryo models (stEMs) also demonstrate unparalleled molecular alignment with the Carnegie Stage 6-7 embryo reference. Thus, stEMs offer state-of-the-art models for advancing our understanding of post-implantation human embryogenesis.

Project description:Human embryo models hold great promise as surrogates for studying development and as platforms for medicine. However, existing models lack efficiency and fidelity in replicating post-implantation stages. Here we asked if STAT3 could reprogram pluripotent stem cells (PSCs) into all blastocyst fates and generate embryo models. Using a medium for enhanced STAT3 activity (SAM), PSCs rapidly reprogram into intermediates that specify all blastocyst fates: hypoblast, trophectoderm and naïve-pluripotent epiblast, within 60 hours. Strikingly, following dissociation of SAM-treated PSCs on 60 or 120 hours and subsequent 3D assembly, structures resembling post-implantation embryos develop within 4 days, with up to 52.41±8.92% efficiency. These exhibited a bilaminar disc-like structure, including epiblast and hypoblast discs, yolk-sac and amniotic cavities, mesenchyme tissue, chorionic cavity, and trophoblast. The STAT3-mediated embryo models (stEMs) also demonstrate unparalleled molecular alignment with the Carnegie Stage 6-7 embryo reference. Thus, stEMs offer state-of-the-art models for advancing our understanding of post-implantation human embryogenesis.

Project description:Human naïve pluripotent cells can differentiate to extraembryonic trophoblast and hypoblast cells. Here we report formation of human blastocyst models by self-organization solely of naïve pluripotent stem cells. The embryo models comprise the three founding lineages, epiblast, trophoblast and hypoblast, arranged to mimic the natural blastocyst. Single-cell RNA sequencing validated the identity of each cell type.

Project description:Our ability to study early human post-implantation development remains highly limited due to the ethical and technical challenges associated with intrauterine development of the human embryo after implantation. Despite the great progress made on human blastoids or gastruloids, such elegant models do not constitute an integrated synthetic stem cell-derived embryoid models (SEMs) that includes all the key extra-embryonic tissues of the early pre-gastrulating implanted human conceptus (e.g. hypoblast, yolk-sac, trophoblasts, amnion and extraembryonic mesoderm), and thus, do not recapitulate post-implantation epiblast development within the context of these extra-embryonic compartments. Mouse naïve pluripotent stem cells (PSCs) have recently been shown to give rise to embryonic and extra-embryonic stem cells capable of self-assembling into post-gastrulation mouse SEMs, while bypassing the blastocyst-like stage, and eventually initiating organogenesis ex utero. Here, we implement critical adaptations to extend these finding in humans, using only genetically unmodified human naïve PSCs, circumventing the need for ectopic expression of lineage promoting transgenes. Such integrated human SEMs recapitulate all known compartments of early post-implantation stage human embryos, including epiblast, hypoblast, extra-embryonic mesoderm, and trophoblast surrounding the latter layers. The organized human SEMs recapitulate key hallmarks of post-implantation stage embryogenesis up to 13-14 days post-fertilization (dpf, Carnegie stage 6a), such as bilaminar disk formation, epiblast lumenogenesis, amniogenesis, anterior-posterior symmetry breaking, PGC specification, primary and secondary yolk sac formation, and extra-embryonic mesoderm expansion that defines a chorionic cavity and a connective stalk. This new platform constitutes a tractable stem cell-based model for experimentally interrogating previously inaccessible windows of human early peri- and post-implantation development.

Project description:Our ability to study early human post-implantation development remains highly limited due to the ethical and technical challenges associated with intrauterine development of the human embryo after implantation. Despite the great progress made on human blastoids or gastruloids, such elegant models do not constitute an integrated synthetic stem cell-derived embryoid models (SEMs) that includes all the key extra-embryonic tissues of the early pre-gastrulating implanted human conceptus (e.g. hypoblast, yolk-sac, trophoblasts, amnion and extraembryonic mesoderm), and thus, do not recapitulate post-implantation epiblast development within the context of these extra-embryonic compartments. Mouse naïve pluripotent stem cells (PSCs) have recently been shown to give rise to embryonic and extra-embryonic stem cells capable of self-assembling into post-gastrulation mouse SEMs, while bypassing the blastocyst-like stage, and eventually initiating organogenesis ex utero. Here, we implement critical adaptations to extend these finding in humans, using only genetically unmodified human naïve PSCs, circumventing the need for ectopic expression of lineage promoting transgenes. Such integrated human SEMs recapitulate all known compartments of early post-implantation stage human embryos, including epiblast, hypoblast, extra-embryonic mesoderm, and trophoblast surrounding the latter layers. The organized human SEMs recapitulate key hallmarks of post-implantation stage embryogenesis up to 13-14 days post-fertilization (dpf, Carnegie stage 6a), such as bilaminar disk formation, epiblast lumenogenesis, amniogenesis, anterior-posterior symmetry breaking, PGC specification, primary and secondary yolk sac formation, and extra-embryonic mesoderm expansion that defines a chorionic cavity and a connective stalk. This new platform constitutes a tractable stem cell-based model for experimentally interrogating previously inaccessible windows of human early peri- and post-implantation development.

Project description:Our ability to study early human post-implantation development remains highly limited due to the ethical and technical challenges associated with intrauterine development of the human embryo after implantation. Despite the great progress made on human blastoids or gastruloids, such elegant models do not constitute an integrated synthetic stem cell-derived embryoid models (SEMs) that includes all the key extra-embryonic tissues of the early pre-gastrulating implanted human conceptus (e.g. hypoblast, yolk-sac, trophoblasts, amnion and extraembryonic mesoderm), and thus, do not recapitulate post-implantation epiblast development within the context of these extra-embryonic compartments. Mouse naïve pluripotent stem cells (PSCs) have recently been shown to give rise to embryonic and extra-embryonic stem cells capable of self-assembling into post-gastrulation mouse SEMs, while bypassing the blastocyst-like stage, and eventually initiating organogenesis ex utero. Here, we implement critical adaptations to extend these finding in humans, using only genetically unmodified human naïve PSCs, circumventing the need for ectopic expression of lineage promoting transgenes. Such integrated human SEMs recapitulate all known compartments of early post-implantation stage human embryos, including epiblast, hypoblast, extra-embryonic mesoderm, and trophoblast surrounding the latter layers. The organized human SEMs recapitulate key hallmarks of post-implantation stage embryogenesis up to 13-14 days post-fertilization (dpf, Carnegie stage 6a), such as bilaminar disk formation, epiblast lumenogenesis, amniogenesis, anterior-posterior symmetry breaking, PGC specification, primary and secondary yolk sac formation, and extra-embryonic mesoderm expansion that defines a chorionic cavity and a connective stalk. This new platform constitutes a tractable stem cell-based model for experimentally interrogating previously inaccessible windows of human early peri- and post-implantation development.

Project description:Our ability to study early human post-implantation development remains highly limited due to the ethical and technical challenges associated with intrauterine development of the human embryo after implantation. Despite the great progress made on human blastoids or gastruloids, such elegant models do not constitute an integrated synthetic stem cell-derived embryoid models (SEMs) that includes all the key extra-embryonic tissues of the early pre-gastrulating implanted human conceptus (e.g. hypoblast, yolk-sac, trophoblasts, amnion and extraembryonic mesoderm), and thus, do not recapitulate post-implantation epiblast development within the context of these extra-embryonic compartments. Mouse naïve pluripotent stem cells (PSCs) have recently been shown to give rise to embryonic and extra-embryonic stem cells capable of self-assembling into post-gastrulation mouse SEMs, while bypassing the blastocyst-like stage, and eventually initiating organogenesis ex utero. Here, we implement critical adaptations to extend these finding in humans, using only genetically unmodified human naïve PSCs, circumventing the need for ectopic expression of lineage promoting transgenes. Such integrated human SEMs recapitulate all known compartments of early post-implantation stage human embryos, including epiblast, hypoblast, extra-embryonic mesoderm, and trophoblast surrounding the latter layers. The organized human SEMs recapitulate key hallmarks of post-implantation stage embryogenesis up to 13-14 days post-fertilization (dpf, Carnegie stage 6a), such as bilaminar disk formation, epiblast lumenogenesis, amniogenesis, anterior-posterior symmetry breaking, PGC specification, primary and secondary yolk sac formation, and extra-embryonic mesoderm expansion that defines a chorionic cavity and a connective stalk. This new platform constitutes a tractable stem cell-based model for experimentally interrogating previously inaccessible windows of human early peri- and post-implantation development.

Project description:Shortly after fertilization, human embryos implant into the uterus. This requires the formation of a blastocyst consisting of a sphere encircling a cavity lodging the embryo proper. Stem cells can form blastocyst models, which we termed blastoid. Here we show that naïve human pluripotent stem cells (hPSCs) triply inhibited for the Hippo, TGFb, and ERK pathways consistently and efficiently (>70%) form blastoids that generate transcriptional pre-implantation (>95%) analogs of the three founding lineages (trophoblast, epiblast, hypoblast), and in the sequential and timely manner of blastocysts. Blastoids spontaneously form an axis marked by maturation of the polar region, which acquires the potential to specifically attach to hormonally-stimulated endometrial cells, as during in utero implantation. Such human blastoids are scalable, versatile, and ethical models to explore human implantation and development.

Project description:The human embryo undergoes morphogenetic transformations following implantation into the uterus and yet our knowledge of this crucial stage is limited by the inability to observe the embryo in vivo. Here, we establish a stem cell-derived human post-implantation embryo model comprised of embryonic and extraembryonic tissues. Overexpression of the transcription factors GATA6 and SOX17 or GATA3 and AP2g in hESCs allowed us to generate hypoblast-like and trophoblast-like cells, respectively. We established conditions to combine these extraembryonic-like cells with wildtype embryonic stem cells and promote their self-organization into structures that mimic aspects of the post-implantation human embryo. These aggregates contain an inner pluripotent epiblast-like domain surrounded by both hypoblast- and trophoblast-like tissues. We show that this human embryo stem cell model robustly generates several cell types, including amnion-, extraembryonic mesenchyme- and primordial germ cell-like cells. Using perturbation experiments, we demonstrated that these populations arise in response to BMP signaling. This model also allowed us to identify an inhibitory role for SOX17 in the specification of anterior hypoblast-like cells. Modulation of the subpopulations in the hypoblast-like compartment demonstrated that these extraembryonic-like cells impact epiblast-like domain differentiation, highlighting functional tissue-tissue crosstalk. In conclusion, this modular, tractable model of the human embryo that includes both embryonic- and extraembryonic-like cells has the potential to probe key questions of human post-implantation development.