Project description:Totipotent embryos lack higher-order genome architecture. In this study, we profile the 3D genome architecture of two putative totipotent cellular models, ciTotiSCs and TBLCs. Notably, both ciTotiSCs and TBLCs retain TADs and structurally resemble ICM/ESCs more closely than totipotent embryos. While TADs and compartmentalization are positionally conserved, they weaken upon acquisition of totipotency. Integrative analysis of epigenetic and Hi-C data further reveal that pluripotency genes undergo coordinated epigenetic landscape remodeling and contact domain reorganization, driving pluripotency suppression. Conversely, totipotency gene activation appears to operate through distinct, yet undefined mechanisms. This study establishes the first functional link between 3D genome folding and totipotency-pluripotency transitions while proposing a revised framework for evaluating in vitro totipotency models.

Project description:Totipotent embryos lack higher-order genome architecture. In this study, we profile the 3D genome architecture of two putative totipotent cellular models, ciTotiSCs and TBLCs. Notably, both ciTotiSCs and TBLCs retain TADs and structurally resemble ICM/ESCs more closely than totipotent embryos. While TADs and compartmentalization are positionally conserved, they weaken upon acquisition of totipotency. Integrative analysis of epigenetic and Hi-C data further reveal that pluripotency genes undergo coordinated epigenetic landscape remodeling and contact domain reorganization, driving pluripotency suppression. Conversely, totipotency gene activation appears to operate through distinct, yet undefined mechanisms. This study establishes the first functional link between 3D genome folding and totipotency-pluripotency transitions while proposing a revised framework for evaluating in vitro totipotency models.

Project description:Totipotent embryos lack higher-order genome architecture. In this study, we profile the 3D genome architecture of two putative totipotent cellular models, ciTotiSCs and TBLCs. Notably, both ciTotiSCs and TBLCs retain TADs and structurally resemble ICM/ESCs more closely than totipotent embryos. While TADs and compartmentalization are positionally conserved, they weaken upon acquisition of totipotency. Integrative analysis of epigenetic and Hi-C data further reveal that pluripotency genes undergo coordinated epigenetic landscape remodeling and contact domain reorganization, driving pluripotency suppression. Conversely, totipotency gene activation appears to operate through distinct, yet undefined mechanisms. This study establishes the first functional link between 3D genome folding and totipotency-pluripotency transitions while proposing a revised framework for evaluating in vitro totipotency models.

Project description:Blastoids, a structure similar to blastocysts in morphological and molecular level, can be applied to regeneration research. Using totipotent cells to construct blastoids will extend the information of early development to an earlier stage, and explore clues of regeneration. Totipotent blastomere-like cells (TBLCs) are a novel type of stably cultured mouse totipotent cell line generated by inhibiting spliceosomes. Here, we constructed blastoids (TBL-blastoids) in a new three-dimensional culture system using TBLCs. Morphological and transcriptomic analysis revealed TBL-blastoids contained typical morphology and key cell lineages of blastocysts and had higher degree of consistency in developmental rate and morphology compared to other blastoids. Moreover, TBL-blastoids implanted into uterus, induced decidua and even developed to embryonic tissues, indicating their in vivo developmental potential. The expansion and structures of TBL-blastoids in the IVC system also showed their in vitro developmental potential. The efficiency of generating TBL-blastoids and implantation rate suggest the necessity of TE-like component formation. Meanwhile, TBLCs can differentiate into extraembryonic cell lines directly, which provides an alternative strategy for evaluating totipotency. Furthermore, we explored the impacts of senescence, a central role in regeneration, on TBLCs and found that cellular senescence impaired the totipotency of TBLCs and the efficiency of generating blastoids. Also, the in vivo and in vitro developmental potential of TBL-blastoids were declined. In conclusion, the induction of TBLCs into blastoids and extraembryonic cells is valuable for promoting regeneration, early embryonic development study and evaluating totipotency.

Project description:Blastoids, a structure similar to blastocysts in morphological and molecular level, can be applied to regeneration research. Using totipotent cells to construct blastoids will extend the information of early development to an earlier stage, and explore clues of regeneration. Totipotent blastomere-like cells (TBLCs) are a novel type of stably cultured mouse totipotent cell line generated by inhibiting spliceosomes. Here, we constructed blastoids (TBL-blastoids) in a new three-dimensional culture system using TBLCs. Morphological and transcriptomic analysis revealed TBL-blastoids contained typical morphology and key cell lineages of blastocysts and had higher degree of consistency in developmental rate and morphology compared to other blastoids. Moreover, TBL-blastoids implanted into uterus, induced decidua and even developed to embryonic tissues, indicating their in vivo developmental potential. The expansion and structures of TBL-blastoids in the IVC system also showed their in vitro developmental potential. The efficiency of generating TBL-blastoids and implantation rate suggest the necessity of TE-like component formation. Meanwhile, TBLCs can differentiate into extraembryonic cell lines directly, which provides an alternative strategy for evaluating totipotency. Furthermore, we explored the impacts of senescence, a central role in regeneration, on TBLCs and found that cellular senescence impaired the totipotency of TBLCs and the efficiency of generating blastoids. Also, the in vivo and in vitro developmental potential of TBL-blastoids were declined. In conclusion, the induction of TBLCs into blastoids and extraembryonic cells is valuable for promoting regeneration, early embryonic development study and evaluating totipotency.

Project description:The 3D genome organization is crucial for gene regulation. Although recent studies have revealed a uniquely relaxed genome conformation in totipotent early blastomeres of both fertilized and cloned embryos, how weakened higher-order chromatin structure is functionally linked to totipotency acquisition remains elusive. Using low-input Hi-C, ATAC-seq, and ChIP-seq, we systematically examined the dynamics of 3D genome and epigenome during pluripotent to totipotent-like state transition in mouse embryonic stem cells (ESCs). The spontaneously converted 2-cell-embryo-like cells (2CLCs) exhibited more relaxed chromatin architecture compared to ESCs, including global weakening of both enhancer-promoter interactions and TAD insulation. While the former correlated with inactivation of ESC enhancers and down-regulation of pluripotent genes, the latter might facilitate contacts between the putative new enhancers arising in 2CLCs and neighboring 2C genes. Importantly, disruption of chromatin organization by depleting CTCF or the cohesin complex promoted the ESC to 2CLC transition. Our results thus establish a critical role of 3D genome organization in totipotency acquisition.

Project description:The 3D genome organization is crucial for gene regulation. Although recent studies have revealed a uniquely relaxed genome conformation in totipotent early blastomeres of both fertilized and cloned embryos, how weakened higher-order chromatin structure is functionally linked to totipotency acquisition remains elusive. Using low-input Hi-C, ATAC-seq, and ChIP-seq, we systematically examined the dynamics of 3D genome and epigenome during pluripotent to totipotent-like state transition in mouse embryonic stem cells (ESCs). The spontaneously converted 2-cell-embryo-like cells (2CLCs) exhibited more relaxed chromatin architecture compared to ESCs, including global weakening of both enhancer-promoter interactions and TAD insulation. While the former correlated with inactivation of ESC enhancers and down-regulation of pluripotent genes, the latter might facilitate contacts between the putative new enhancers arising in 2CLCs and neighboring 2C genes. Importantly, disruption of chromatin organization by depleting CTCF or the cohesin complex promoted the ESC to 2CLC transition. Our results thus establish a critical role of 3D genome organization in totipotency acquisition.

Project description:The 3D genome organization is crucial for gene regulation. Although recent studies have revealed a uniquely relaxed genome conformation in totipotent early blastomeres of both fertilized and cloned embryos, how weakened higher-order chromatin structure is functionally linked to totipotency acquisition remains elusive. Using low-input Hi-C, ATAC-seq, and ChIP-seq, we systematically examined the dynamics of 3D genome and epigenome during pluripotent to totipotent-like state transition in mouse embryonic stem cells (ESCs). The spontaneously converted 2-cell-embryo-like cells (2CLCs) exhibited more relaxed chromatin architecture compared to ESCs, including global weakening of both enhancer-promoter interactions and TAD insulation. While the former correlated with inactivation of ESC enhancers and down-regulation of pluripotent genes, the latter might facilitate contacts between the putative new enhancers arising in 2CLCs and neighboring 2C genes. Importantly, disruption of chromatin organization by depleting CTCF or the cohesin complex promoted the ESC to 2CLC transition. Our results thus establish a critical role of 3D genome organization in totipotency acquisition.

Project description:Somatic cell nuclear transfer (SCNT) can reprogram a somatic nucleus to a totipotent state. However, the re-organization of three-dimensional chromatin structure in this process remains poorly understood. Using low-input Hi-C, we revealed that during SCNT, the transferred nucleus first enters a mitotic-like state (premature chromatin condensation). Unlike fertilized embryos, SCNT embryos show stronger TADs at the 1-cell stage. TADs become weaker at the 2-cell stage, followed by gradual consolidation. Compartments A/B are markedly weak in 1-cell SCNT embryos and become increasingly strengthened afterward. By the 8-cell stage, somatic chromatin architecture is largely reset to embryonic patterns. Unexpectedly, we found cohesin represses minor zygotic genome activation (ZGA) genes (2-cell specific genes) in pluripotent and differentiated cells, and pre-depleting cohesin in donor cells facilitates minor ZGA and SCNT. These data reveal multi-step reprogramming of 3D chromatin architecture during SCNT and support dual roles of cohesin in TAD formation and minor ZGA repression.

Project description:Fertilization transforms sperm and egg into a totipotent embryo but the underlying mechanisms are unknown. We here report that gene expression initiates during the gamete-to-embryo transition in mouse embryos. Meiotic exit induced by sperm entry enhances a transcriptionally-permissive epigenetic landscape. Time-course analysis of single embryos revealed a succession of genome-wide transcription 'ripples' initiating within 2 hours. Disrupting key pluripotency transcription factor levels prior to sperm entry had little immediate effect, indicating that different mechanisms engender pluripotent and totipotent states. These findings suggest that a hierarchical gene expression program characterizes the emergence of totipotency during the gamete-to-embryo transition, with broad mechanistic implications for the reprogramming of cellular potency.