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Totipotency is the ability of a single cell to give rise to all of the differentiated cell types that build the conceptus, yet how to capture this property in vitro remains incompletely understood. Defining totipotency relies on a variety of assays of variable stringency. Here, we describe criteria to define totipotency. We explain how distinct criteria of increasing stringency can be used to judge totipotency by evaluating candidate totipotent cell types in mice, including early blastomeres and expanded or extended pluripotent stem cells. Our data challenge the notion that expanded or extended pluripotent states harbour increased totipotent potential relative to conventional embryonic stem cells under in vitro and in vivo conditions. Posfai, Schell, Janiszewski et al. assess candidate totipotent stem cells with in vitro and in vivo assays of increasing stringency to evaluate their developmental potential and lineage contributions.

Embryonic stem (ES) cells are derived from blastocyst-stage embryos and are thought to be functionally equivalent to the inner cell mass, which lacks the ability to produce all extraembryonic tissues. Here we identify a rare transient cell population within mouse ES and induced pluripotent stem (iPS) cell cultures that expresses high levels of transcripts found in two-cell (2C) embryos in which the blastomeres are totipotent. We genetically tagged these 2C-like ES cells and show that they lack the inner cell mass pluripotency proteins Oct4 (also known as Pou5f1), Sox2 and Nanog, and have acquired the ability to contribute to both embryonic and extraembryonic tissues. We show that nearly all ES cells cycle in and out of this privileged state, which is partially controlled by histone-modifying enzymes. Transcriptome sequencing and bioinformatic analyses showed that many 2C transcripts are initiated from long terminal repeats derived from endogenous retroviruses, suggesting this foreign sequence has helped to drive cell-fate regulation in placental mammals. A rare cell subpopulation within mouse embryonic stem cell cultures is identified that exhibits properties of two-cell (2C) embryos; the interconversion of ES cells to 2C cells correlates with endogenous retroviral activity. Retrovirus-primed stem cells Mouse embryos progressively lose totipotency — the ability to develop into all embryonic and extraembryonic cell types, and to develop as a live animal — after the two-cell embryo stage. Embryonic stem (ES) cells, derived from the inner cell mass of the later blastocyst stage, are thought to be unable to contribute to extraembryonic tissue. Now, Samuel Pfaff and colleagues report a rare population in cultured ES cells that expresses transcripts previously found only in two-cell embryos and that has the potential to develop into extraembryonic tissue. Almost all ES cells transiently enter this privileged two-cell-like state, regulated in part by histone-modification enzymes. Interestingly, many of the two-cell-like-embryo transcripts are initiated by endogenous retrovirus-like elements, suggesting that placental mammals have hijacked foreign sequences for cell-fate regulation.

In mice, only the zygotes and blastomeres from 2-cell embryos are authentic totipotent stem cells (TotiSCs) capable of producing all the differentiated cells in both embryonic and extraembryonic tissues and forming an entire organism 1 . However, it remains unknown whether and how totipotent stem cells can be established in vitro in the absence of germline cells. Here we demonstrate the induction and long-term maintenance of TotiSCs from mouse pluripotent stem cells using a combination of three small molecules: the retinoic acid analogue TTNPB, 1-azakenpaullone and the kinase blocker WS6. The resulting chemically induced totipotent stem cells (ciTotiSCs), resembled mouse totipotent 2-cell embryo cells at the transcriptome, epigenome and metabolome levels. In addition, ciTotiSCs exhibited bidirectional developmental potentials and were able to produce both embryonic and extraembryonic cells in vitro and in teratoma. Furthermore, following injection into 8-cell embryos, ciTotiSCs contributed to both embryonic and extraembryonic lineages with high efficiency. Our chemical approach to totipotent stem cell induction and maintenance provides a defined in vitro system for manipulating and developing understanding of the totipotent state and the development of multicellular organisms from non-germline cells. Under chemically defined conditions, mouse pluripotent stem cells can be induced to closely resemble authentic totipotent stem cells that can differentiate to both embryonic and extraembryonic lineages.

Reprogramming of adult cells to generate induced pluripotent stem cells (iPS cells) has opened new therapeutic opportunities; however, little is known about the possibility of in vivo reprogramming within tissues. Here we show that transitory induction of the four factors Oct4, Sox2, Klf4 and c-Myc in mice results in teratomas emerging from multiple organs, implying that full reprogramming can occur in vivo . Analyses of the stomach, intestine, pancreas and kidney reveal groups of dedifferentiated cells that express the pluripotency marker NANOG, indicative of in situ reprogramming. By bone marrow transplantation, we demonstrate that haematopoietic cells can also be reprogrammed in vivo . Notably, reprogrammable mice present circulating iPS cells in the blood and, at the transcriptome level, these in vivo generated iPS cells are closer to embryonic stem cells (ES cells) than standard in vitro generated iPS cells. Moreover, in vivo iPS cells efficiently contribute to the trophectoderm lineage, suggesting that they achieve a more plastic or primitive state than ES cells. Finally, intraperitoneal injection of in vivo iPS cells generates embryo-like structures that express embryonic and extraembryonic markers. We conclude that reprogramming in vivo is feasible and confers totipotency features absent in standard iPS or ES cells. These discoveries could be relevant for future applications of reprogramming in regenerative medicine. Induced pluripotent stem cells (iPS cells) have been created in vivo by reprogramming mouse somatic cells with Oct4 , Sox2 , Klf4 and c-Myc ; these cells have totipotent features that are missing from in vitro created iPS cells or embryonic stem cells. In vivo production of iPS cells Manuel Serrano and colleagues show for the first time that reprogramming of somatic cells to pluripotency by the classic 'Yamanaka factors' Oct4, Sox2, Klf4 and c-Myc can be achieved in vivo . Analysis of induced pluripotent stem (iPS) cells induced in vivo from stomach, intestine, pancreas and kidney cells in mice shows that they are closer to embryonic stem cells than in vitro -generated iPS cells. The in vivo iPS cells also have the potential to generate embryo-like structures that express embryonic and extraembryonic markers, which suggests that they have totipotent features not found in conventional iPS or embryonic stem cells.

Using a single-nucleus Hi-C protocol, the authors find that spatial organization of chromatin during oocyte-to-zygote transition differs between paternal and maternal nuclei within a single-cell zygote. Oocyte-to-zygote chromatin reorganization It has been difficult to investigate chromosome organization in early embryos with genomic techniques owing to the paucity of cellular material. Here, Kikuë Tachibana-Konwalski and colleagues have developed a single-nucleus Hi-C protocol, which they apply to investigate chromatin organization during the developmental transition from oocytes to zygotes in mice. They find that chromatin architecture is distinct in the paternal and maternal pronuclei within a single-cell zygote. Zygotic maternal nuclei contain topological domains and loops but no A–B compartments, whereas compartments can be observed in paternal nuclei. Clusters of contacts are variable between individual cells and do not always match topological domains across populations. The authors propose that the organization of zygotic maternal chromatin represents a transition state towards that of totipotent cells. Chromatin is reprogrammed after fertilization to produce a totipotent zygote with the potential to generate a new organism 1 . The maternal genome inherited from the oocyte and the paternal genome provided by sperm coexist as separate haploid nuclei in the zygote. How these two epigenetically distinct genomes are spatially organized is poorly understood. Existing chromosome conformation capture-based methods 2 , 3 , 4 , 5 are not applicable to oocytes and zygotes owing to a paucity of material. To study three-dimensional chromatin organization in rare cell types, we developed a single-nucleus Hi-C (high-resolution chromosome conformation capture) protocol that provides greater than tenfold more contacts per cell than the previous method 2 . Here we show that chromatin architecture is uniquely reorganized during the oocyte-to-zygote transition in mice and is distinct in paternal and maternal nuclei within single-cell zygotes. Features of genomic organization including compartments, topologically associating domains (TADs) and loops are present in individual oocytes when averaged over the genome, but the presence of each feature at a locus varies between cells. At the sub-megabase level, we observed stochastic clusters of contacts that can occur across TAD boundaries but average into TADs. Notably, we found that TADs and loops, but not compartments, are present in zygotic maternal chromatin, suggesting that these are generated by different mechanisms. Our results demonstrate that the global chromatin organization of zygote nuclei is fundamentally different from that of other interphase cells. An understanding of this zygotic chromatin ‘ground state’ could potentially provide insights into reprogramming cells to a state of totipotency.

Substantial epigenetic resetting during early embryo development from fertilization to blastocyst formation ensures zygotic genome activation and leads to progressive cellular heterogeneities 1 , 2 – 3 . Mapping single-cell epigenomic profiles of core histone modifications that cover each individual cell is a fundamental goal in developmental biology. Here we develop target chromatin indexing and tagmentation (TACIT), a method that enabled genome-coverage single-cell profiling of seven histone modifications across mouse early embryos. We integrated these single-cell histone modifications with single-cell RNA sequencing data to chart a single-cell resolution epigenetic landscape. Multimodal chromatin-state annotations showed that the onset of zygotic genome activation at the early two-cell stage already primes heterogeneities in totipotency. We used machine learning to identify totipotency gene regulatory networks, including stage-specific transposable elements and putative transcription factors. CRISPR activation of a combination of these identified transcription factors induced totipotency activation in mouse embryonic stem cells. Together with single-cell co-profiles of multiple histone modifications, we developed a model that predicts the earliest cell branching towards the inner cell mass and the trophectoderm in latent multimodal space and identifies regulatory elements and previously unknown lineage-specifying transcription factors. Our work provides insights into single-cell epigenetic reprogramming, multimodal regulation of cellular lineages and cell-fate priming during mouse pre-implantation development. Two new methods, target chromatin indexing and tagmentation (TACIT) and combined TACIT (CoTACIT), enabled single-cell profiling of the epigenome and lineage tracing from mouse zygotes to blastocysts.

In mammals, telomere protection is mediated by the essential protein TRF2, which binds chromosome ends and ensures genome integrity 1 , 2 . TRF2 depletion results in end-to-end chromosome fusions in all cell types that have been tested so far. Here we find that TRF2 is dispensable for the proliferation and survival of mouse embryonic stem (ES) cells. Trf2 −/− (also known as Terf2 ) ES cells do not exhibit telomere fusions and can be expanded indefinitely. In response to the deletion of TRF2, ES cells exhibit a muted DNA damage response that is characterized by the recruitment of γH2AX—but not 53BP1—to telomeres. To define the mechanisms that control this unique DNA damage response in ES cells, we performed a CRISPR–Cas9-knockout screen. We found a strong dependency of TRF2-null ES cells on the telomere-associated protein POT1B and on the chromatin remodelling factor BRD2. Co-depletion of POT1B or BRD2 with TRF2 restores a canonical DNA damage response at telomeres, resulting in frequent telomere fusions. We found that TRF2 depletion in ES cells activates a totipotent-like two-cell-stage transcriptional program that includes high levels of ZSCAN4. We show that the upregulation of ZSCAN4 contributes to telomere protection in the absence of TRF2. Together, our results uncover a unique response to telomere deprotection during early development. Depletion of TRF2—an essential mediator of telomere protection in most mammalian cells—in mouse embryonic stem cells activates a compensatory transcriptional program that renders TRF2 dispensable for their survival and proliferation.

Totipotency refers to the ability of a cell to generate all of the cell types of an organism. Unlike pluripotency, the establishment of totipotency is poorly understood. In mouse embryonic stem cells, Dux drives a small percentage of cells into a totipotent state by expressing 2-cell-embryo-specific transcripts. To understand how this transition takes place, we performed single-cell RNA-seq, which revealed a two-step transcriptional reprogramming process characterized by downregulation of pluripotent genes in the first step and upregulation of the 2-cell-embryo-specific elements in the second step. To identify factors controlling the transition, we performed a CRISPR–Cas9-mediated screen, which revealed Myc and Dnmt1 as two factors preventing the transition. Mechanistic studies demonstrate that Myc prevents downregulation of pluripotent genes in the first step, while Dnmt1 impedes 2-cell-embryo-specific gene activation in the second step. Collectively, the findings of our study reveal insights into the establishment and regulation of the totipotent state in mouse embryonic stem cells. Fu et al. report the transition of ESCs into a 2-cell-embyro-like state induced by Dux involves two steps and can be prevented by Myc and Dnmt1, which inhibit the downregulation of pluripotency genes and the activation of 2C + -upregulated elements.

Key Points Major epigenetic reprogramming occurs during pre-implantation development. The precise functions of these changes in cell fate allocation remain to be addressed. Genetic approaches in the past have uncovered important principles and players involved in lineage allocation during pre-implantation development. Recently, single-cell expression profiling and novel microscopy techniques have provided new insights into transcriptional and chromatin-regulated events that are responsible for lineage allocation. Global chromatin mobility, as well as differential expression of chromatin modifiers in single cells, might promote cell fate allocation in the early embryo. Future research focusing on single cells will provide key insights into the mechanisms that drive and enforce cell fate allocation decisions. It is unclear how totipotent embryonic cells acquire their fate and what role chromatin dynamics have in this process. Technological advances in studying single cells have begun to improve our understanding of the mechanisms underlying lineage allocation and cell plasticity in early mammalian development. Following fertilization, gametes undergo epigenetic reprogramming in order to revert to a totipotent state. How embryonic cells subsequently acquire their fate and the role of chromatin dynamics in this process are unknown. Genetic and experimental embryology approaches have identified some of the players and morphological changes that are involved in early mammalian development, but the exact events underlying cell fate allocation in single embryonic cells have remained elusive. Experimental and technological advances have recently provided novel insights into chromatin dynamics and nuclear architecture in single cells; these insights have reshaped our understanding of the mechanisms underlying cell fate allocation and plasticity in early mammalian development.

Totipotent cells hold enormous potential for regenerative medicine. Thus, the development of cellular models recapitulating totipotent-like features is of paramount importance. Cells resembling the totipotent cells of early embryos arise spontaneously in mouse embryonic stem (ES) cell cultures. Such ‘2-cell-like-cells’ (2CLCs) recapitulate 2-cell-stage features and display expanded cell potential. Here, we used 2CLCs to perform a small-molecule screen to identify new pathways regulating the 2-cell-stage program. We identified retinoids as robust inducers of 2CLCs and the retinoic acid (RA)-signaling pathway as a key component of the regulatory circuitry of totipotent cells in embryos. Using single-cell RNA-seq, we reveal the transcriptional dynamics of 2CLC reprogramming and show that ES cells undergo distinct cellular trajectories in response to RA. Importantly, endogenous RA activity in early embryos is essential for zygotic genome activation and developmental progression. Overall, our data shed light on the gene regulatory networks controlling cellular plasticity and the totipotency program. High-throughput chemical screening identifies retinoic acid signaling as a regulatory pathway of 2-cell-like cell reprogramming and early mouse development.