Project description:Gastruloids have recently emerged as an efficient four-dimensional model for studying some aspects of post-implantation embryonic patterning. Their ability to undergo gastrulation-like processes leading to the self-organization into highly reproducible biological objects, has opened new avenues to investigate early embryonic patterning. Here, we sought to uncover the molecular and cellular mechanism underlying this remarkable property. We report that self-organization competence is associated with a cell-specific coordination of a Cadherin switch. We find that N-Cadherin hinders gastruloids morphogenetic competence, for its inactivation leads to the formation of trunk-like structures without relying on the otherwise requested extra-cellular matrix analogues such as Matrigel. In contrast, the repression of E-Cadherin by Snai1 is critical for self-organization: Snai1 establishes a cell-specific repressive pace by triggering the repression of a pluripotency-associated transcription program and its chromatin landscape, thus allowing a proper transition from E- to N-Cadherin to occur. Altogether, this work establishes a molecular mechanism that integrates the exit from pluripotency and the pace of cell differentiation, leading to the observed self-organizing potential of gastruloids.

Project description:Gastruloids have recently emerged as an efficient four-dimensional model for studying some aspects of post-implantation embryonic patterning. Their ability to undergo gastrulation-like processes leading to the self-organization into highly reproducible biological objects, has opened new avenues to investigate early embryonic patterning. Here, we sought to uncover the molecular and cellular mechanism underlying this remarkable property. We report that self-organization competence is associated with a cell-specific coordination of a Cadherin switch. We find that N-Cadherin hinders gastruloids morphogenetic competence, for its inactivation leads to the formation of trunk-like structures without relying on the otherwise requested extra-cellular matrix analogues such as Matrigel. In contrast, the repression of E-Cadherin by Snai1 is critical for self-organization: Snai1 establishes a cell-specific repressive pace by triggering the repression of a pluripotency-associated transcription program and its chromatin landscape, thus allowing a proper transition from E- to N-Cadherin to occur. Altogether, this work establishes a molecular mechanism that integrates the exit from pluripotency and the pace of cell differentiation, leading to the observed self-organizing potential of gastruloids.

Project description:Gastruloids have recently emerged as an efficient four-dimensional model for studying some aspects of post-implantation embryonic patterning. Their ability to undergo gastrulation-like processes leading to the self-organization into highly reproducible biological objects, has opened new avenues to investigate early embryonic patterning. Here, we sought to uncover the molecular and cellular mechanism underlying this remarkable property. We report that self-organization competence is associated with a cell-specific coordination of a Cadherin switch. We find that N-Cadherin hinders gastruloids morphogenetic competence, for its inactivation leads to the formation of trunk-like structures without relying on the otherwise requested extra-cellular matrix analogues such as Matrigel. In contrast, the repression of E-Cadherin by Snai1 is critical for self-organization: Snai1 establishes a cell-specific repressive pace by triggering the repression of a pluripotency-associated transcription program and its chromatin landscape, thus allowing a proper transition from E- to N-Cadherin to occur. Altogether, this work establishes a molecular mechanism that integrates the exit from pluripotency and the pace of cell differentiation, leading to the observed self-organizing potential of gastruloids.

Project description:Human gastrulation is a dynamic, complex, and poorly understood process. Starting from a seemingly homogenous population, cell and tissue organization during this process establishes the 3D organismal body plan. However, due to technical and ethical limitations, mechanisms of human gastrulation are largely unexplored. For example, it is generally unclear whether a spatially ordered, external cue is necessary for patterning, or whether the epiblast harbors the innate ability to differentiate and self-organize in the absence of asymmetric cues. Human pluripotent stem cells (hPSCs) fortunately offer the potential to model gastrulation, most notably through generation of 3D “gastruloids”. Here we use optogenetic control of Wnt signaling to establish a 3D hPSC gastruloid model and demonstrate the spatially-ordered emergence of the three germ layer lineages in the absence of exogenous asymmetrical cues.

Project description:It has now become clear that the process of fate specification during early embryogenesis is mediated by a handful of key signaling pathways. However, how the temporal and spatial integration of these signals plays out to give rise to self-organization of tissues remains obscure. Here we use artificial human gastruloids and quantitative single-cell analysis to dissect the temporal integration of two key pathways WNT and ACTIVIN that along with BMP control gastrulation and primitive streak patterning in model systems. We showed that ACTIVIN elicits a transient signaling response, as well as a transient induction of differentiation. However, unlike BMP and WNT, ACTIVIN cannot induce stable primitive streak formation and mesodermal patterning. Pre-exposure to WNT switches the response of cells to ACTIVIN whereby it becomes a concentration dependent morphogen. This provides evidence for WNT signaling memory that occurs at the transcriptional level and not as a modifier of ACTIVIN signaling dynamics.

Project description:Stem cell models that replicate the gastrulation process in human embryos have been created, but they lack the essential extraembryonic cells needed for early embryonic development and patterning. Here, we introduce a robust and efficient method that prompts human extended pluripotent stem (EPS) cells to self-organize into embryo-like structures, called peri-gastruloids, which encompass both embryonic (epiblast) and extraembryonic (hypoblast) tissues. These peri-gastruloids simulate critical stages of human peri-gastrulation development, such as forming amniotic and yolk sac cavities, developing bilaminar and trilaminar embryonic discs, specifying primordial germ cells, initiating gastrulation, and early neurulation. Single-cell RNA sequencing unveiled transcriptomic characteristics of these human peri-gastruloids, which closely resemble the primary peri-gastrulation cell types found in human and non-human primates. Our results emphasize the remarkable self-organizing ability of EPS cells to generate advanced human embryo-like structures. This peri-gastruloid platform allows for further exploration beyond gastrulation and may potentially aid in the development of human fetal tissues for use in regenerative medicine.

Project description:Gastruloids are three-dimensional aggregates of embryonic stem cells (ESCs) that display key features of mammalian post-implantation development, including germ layer specification and axial organization. Gastruloids have mostly been characterized with microscopy-based approaches, limiting the number of genes that can be explored. It is therefore unclear to what extent gene expression in gastruloids reflects in vivo embryonic expression. Using both single-cell RNA-seq (scRNA-seq) and spatial transcriptomics we systematically compared cell types and spatial expression patterns between mouse gastruloids and mouse embryos.

Project description:Patterning and growth are fundamental features of embryonic development that must be tightly coordinated during morphogenesis. While metabolism is known to control cell growth, how it impacts patterning and links to morphogenesis is poorly understood. To understand how metabolism impacts early mesoderm specification during gastrulation, we used in vitro mouse embryonic stem (ES) cell-derived gastruloids, due to ease of metabolic manipulations and high-throughput nature. Gastruloids showed mosaic expression of glucose transporters co-expressing with the mesodermal marker T/Bra. To understand the significance of cellular glucose uptake in development, we used the glucose metabolism inhibitor 2-deoxy-D-glucose (2-DG). 2-DG blocked the expression of T/Bra and abolishes axial elongation in gastruloids. Surprisingly, removing glucose completely from the medium did not phenocopy 2-DG treatment despite a significant decline in glycolytic intermediates occurring under both conditions. As 2-DG can also act as a competitive inhibitor of mannose in protein glycosylation, we added mannose together with 2-DG and found that it could rescue the mesoderm specification. We corroborated these results in vivomouse embryos where supplementing mannose rescued the 2-DG mediated phenotype of mesoderm specification and proximo-distal elongation of the primitive streak. We further showed that blocking production and intracellular recycling of mannose abrogated mesoderm specification. At molecular level, proteomics analysis revealed that mannose reversed glycosylation of the Wnt pathway regulator, Secreted Frizzled Receptor, Frzb, expressed in the primitive streak of the mouse embryo. Our study showed how mannose linked metabolism to glycosylation of a developmental pathway component, crucial in patterning of mesoderm and morphogenesis of gastruloids.

Project description:Single cell transcriptomic study (using 10x Genomics v3 kits) of gastruloids, aggregates of mESCs, at different developmental timepoints (24h, 48h and 72h post-aggregation). mESCs, corresponding to the 0h timepoint, were also sequenced. The aim of this study was to delineate the cell state transition dynamics underlying anteroposterior symmetry breaking and germ layer formation in gastruloids. Gastruloids used in this study were generated from Bra::GFP reporter mESCs (Fehling et al., 2003).

Project description:Self-elongating neural tube organoids recapitulate key aspects of the morphology, anterior-posterior patterning, neural crest emergence and neural differentiation of mouse embryo in vivo by self-organization. We used single-cell RNA sequencing (scRNA-seq) to analyse the cell types and to reveal the sequence of transcriptional events in the emergence of neural crest cells and neural differentiation.