Project description:Gastrulation is a critical stage in embryonic development during which the germ layers are established. The advances and increasing availability of sequencing technologies led to the identification of gene regulatory programs that control the emergence of the germ layers and its derivatives. However, proteome-based studies of early mammalian development are scarce. To overcome this, we utilized gastruloids and a multilayered mass spectrometry-based proteomics approach to investigate the global dynamics of (phospho)protein expression during gastruloid differentiation. Our findings revealed that many proteins exhibit temporal expression with unique expression profiles corresponding to the three germ layers, which we also validated using single-cell proteomics technology. Notably, detected temporal protein expression dynamics in gastruloids aligns with equivalent mouse embryo stages. Additionally, we profiled enhancer interaction landscapes using P300 proximity labeling, which revealed numerous gastruloid-specific transcription factors and chromatin remodelers. Subsequent degron-based perturbations combined with scRNA-seq identified a critical role for ZEB2 in regulating mouse and human somitogenesis. Overall, this study provides a rich resource for developmental and synthetic biology communities endeavoring to understand mammalian embryogenesis.

Project description:Gastrulation is a critical stage of embryonic development during which the three germ layers are established. Deciphering the molecular mechanisms underlying this proces from a protein perspective remains a significant challenge. To address this, we employed a multilayered mass spectrometry-based proteomics approach to investigate the global dynamics of (phospho)protein expression during differentiation of ESCs towards gastruloids – an in vitro model of gastrulation-stage embryogenesis. Our findings revealed that many proteins exhibited temporal expression with unique expression profiles corresponding to the three germ layers. Additionally, we profiled enhancer interaction landscapes in ESCs and gastruloids using p300 proximity labeling, which revealed numerous gastruloid-specific transcription factors and chromatin remodelers. Subsequent degron based perturbations combined with scRNA-seq revealed a critical role for Zeb2 in regulating mouse and human somitogenesis. Overall, this study provides a rich resource for developmental and synthetic biology communities endeavoring to understand mammalian embryogenesis.

Project description:Gastrulation is a critical stage in embryonic development during which the germ layers are established. The advances and increasing availability of sequencing technologies led to the identification of gene regulatory programs that control the emergence of the germ layers and its derivatives. However, proteome-based studies of early mammalian development are scarce. To overcome this, we utilized gastruloids and a multilayered mass spectrometry-based proteomics approach to investigate the global dynamics of (phospho)protein expression during gastruloid differentiation. Our findings revealed that many proteins exhibit temporal expression with unique expression profiles corresponding to the three germ layers, which we also validated using single-cell proteomics technology. Notably, detected temporal protein expression dynamics in gastruloids aligns with equivalent mouse embryo stages. Additionally, we profiled enhancer interaction landscapes using P300 proximity labeling, which revealed numerous gastruloid-specific transcription factors and chromatin remodelers. Subsequent degron-based perturbations combined with scRNA-seq identified a critical role for ZEB2 in regulating mouse and human somitogenesis. Overall, this study provides a rich resource for developmental and synthetic biology communities endeavoring to understand mammalian embryogenesis.

Project description:Gastruloids are highly scalable, three-dimensional assemblies generated from pluripotent stem cells that recapitulate fundamental principles of embryonic pattern formation in vitro. Using single cell RNA and multiome sequencing we provide a comprehensive resource mapping cellular states and cell types found during gastruloid development and compare them to the in vivo embryo. We further develop a high throughput gastruloid handling and imaging pipeline to spatially monitor cell type emergence and unfolding of symmetry breaking during gastruloid development. We report spatial variability of pluripotency states in early gastruloids that determines a binary cell response to Wnt activation. While cells situated in the core of the gastruloid revert to an ectopic pluripotent state, peripheral cells differentiate to a primitive streak like state. These two populations then cause gastruloids to break radial symmetry, allowing axial elongation and commitment to the three embryonic germ layers. Finally by performing a phenotypic compound screen, we perturb thousands of gastruloids at relevant developmental time points deriving a phenotypic landscape and inferring molecular regulator networks underlying gastruloid development. Employing this resource, we improve the formation of anterior structures in the existing gastruloid model, using a dual Wnt modulation approach to differentiate an anterior ectopic pluripotent core to anterior ecto- and endodermal structures. This work gives is a resource to understand how gastruloids develop and, more generally, how homogenous cell populations can generate complex patterns in vitro.

Project description:Gastrulation is a critical stage of embryonic development during which the three germ layers are established. Deciphering the molecular mechanisms underlying this process from a protein perspective remains a significant challenge. To address this, we employed a multilayered mass spectrometry-based proteomics approach to investigate the global dynamics of (phospho)protein expression during differentiation of ESCs towards gastruloids – an in vitro model of gastrulation-stage embryogenesis. Our findings revealed that many proteins exhibited temporal expression during gastrulation with unique expression profiles corresponding to the three germ layers, which we also validated using an ultra sensitive single cell proteomics approachtechnology. Additionally, we profiled enhancer interaction landscapes in ESCs and gastruloids using p300 proximity labeling, which revealed numerous gastruloid-specific transcription factors and chromatin remodelers. Subsequent degron based perturbations combined with scRNA-seq revealed a critical role for Zeb2 in regulating mouse and human somitogenesis. Overall, this study provides a rich resource for developmental and synthetic biology communities endeavoring to understand mammalian embryogenesis.

Project description:Gastrulation is a critical stage of embryonic development during which the three germ layers are established. Deciphering the molecular mechanisms underlying this proces from a protein perspective remains a significant challenge. To address this, we employed a multilayered mass spectrometry-based proteomics approach to investigate the global dynamics of (phospho)protein expression during differentiation of ESCs towards gastruloids – an in vitro model of gastrulation-stage embryogenesis. Our findings revealed that many proteins exhibited temporal expression with unique expression profiles corresponding to the three germ layers. Additionally, we profiled enhancer interaction landscapes in ESCs and gastruloids using p300 proximity labeling, which revealed numerous gastruloid-specific transcription factors and chromatin remodelers. Subsequent degron based perturbations combined with scRNA-seq revealed a critical role for Zeb2 in regulating mouse and human somitogenesis. Overall, this study provides a rich resource for developmental and synthetic biology communities endeavoring to understand mammalian embryogenesis.

Project description:Gastrulation is a critical stage of embryonic development during which the three germ layers are established. Deciphering the molecular mechanisms underlying this proces from a protein perspective remains a significant challenge. To address this, we employed a multilayered mass spectrometry-based proteomics approach to investigate the global dynamics of (phospho)protein expression during differentiation of ESCs towards gastruloids – an in vitro model of gastrulation-stage embryogenesis. Our findings revealed that many proteins exhibited temporal expression with unique expression profiles corresponding to the three germ layers. Additionally, we profiled enhancer interaction landscapes in ESCs and gastruloids using p300 proximity labeling, which revealed numerous gastruloid-specific transcription factors and chromatin remodelers. Subsequent degron based perturbations combined with scRNA-seq revealed a critical role for Zeb2 in regulating mouse and human somitogenesis. Overall, this study provides a rich resource for developmental and synthetic biology communities endeavoring to understand mammalian embryogenesis.

Project description:Gastrulation is a critical stage of embryonic development during which the three germ layers are established. Deciphering the molecular mechanisms underlying this proces from a protein perspective remains a significant challenge. To address this, we employed a multilayered mass spectrometry-based proteomics approach to investigate the global dynamics of (phospho)protein expression during differentiation of ESCs towards gastruloids – an in vitro model of gastrulation-stage embryogenesis. Our findings revealed that many proteins exhibited temporal expression with unique expression profiles corresponding to the three germ layers. Additionally, we profiled enhancer interaction landscapes in ESCs and gastruloids using p300 proximity labeling, which revealed numerous gastruloid-specific transcription factors and chromatin remodelers. Subsequent degron based perturbations combined with scRNA-seq revealed a critical role for Zeb2 in regulating mouse and human somitogenesis. Overall, this study provides a rich resource for developmental and synthetic biology communities endeavoring to understand mammalian embryogenesis.

Project description:Correct gene expression levels in space and time are crucial for normal development. Advances in genomics enable the inference of gene regulatory programs that are active during development. However, this approach cannot capture the complex multicellular interactions that occur in embryogenesis. Compared to model organisms such as fruit flies and zebrafish, the growth of mammalian embryos in utero further complicates the analysis of cell-cell communication during development. However, in vitro models of mammalian development such as gastruloids allow to overcome this limitation. Using time-resolved single-cell chromatin accessibility analysis, we have delineated the regulatory landscape during gastruloid development and thereby identified the critical drivers of developmental transitions. We observed that gastruloids develop from pluripotent cells driven by the transcription factor (TF) dimer OCT4-SOX2 and differentiate along two main branches. A mesoderm branch driven by the TF MSGN1 and a spinal cord branch driven by CDX1, 2, 4 (CDX). Consistent with our lineage reconstruction, ΔCDX gastruloids fail to form spinal cord. Conversely, Msgn1 ablation inhibits the development of paraxial mesoderm, as expected. However, this also abolished spinal cord cells, which is surprising given that MSGN1 is not associated with differentiation along this branch. Therefore, formation of paraxial mesoderm is required for spinal cord development. To validate this, we generated chimeric gastruloids using ΔMSGN1 and wildtype cells, which formed both spinal cord and paraxial mesoderm. Strikingly, ΔMsgn1 cells specifically contributed to spinal cord, suggesting that cell-cell interactions between paraxial mesoderm and spinal cord are necessary for the formation the latter. Our work has important implications for the study of cell-cell communication in development and how the bridge can be made between gene regulatory programs and complex multicellular developmental structures.

Project description:Correct gene expression levels in space and time are crucial for normal development. Advances in genomics enable the inference of gene regulatory programs that are active during development. However, this approach cannot capture the complex multicellular interactions that occur in embryogenesis. Compared to model organisms such as fruit flies and zebrafish, the growth of mammalian embryos in utero further complicates the analysis of cell-cell communication during development. However, in vitro models of mammalian development such as gastruloids allow to overcome this limitation. Using time-resolved single-cell chromatin accessibility analysis, we have delineated the regulatory landscape during gastruloid development and thereby identified the critical drivers of developmental transitions. We observed that gastruloids develop from pluripotent cells driven by the transcription factor (TF) dimer OCT4-SOX2 and differentiate along two main branches. A mesoderm branch driven by the TF MSGN1 and a spinal cord branch driven by CDX1, 2, 4 (CDX). Consistent with our lineage reconstruction, ΔCDX gastruloids fail to form spinal cord. Conversely, Msgn1 ablation inhibits the development of paraxial mesoderm, as expected. However, this also abolished spinal cord cells, which is surprising given that MSGN1 is not associated with differentiation along this branch. Therefore, formation of paraxial mesoderm is required for spinal cord development. To validate this, we generated chimeric gastruloids using ΔMSGN1 and wildtype cells, which formed both spinal cord and paraxial mesoderm. Strikingly, ΔMsgn1 cells specifically contributed to spinal cord, suggesting that cell-cell interactions between paraxial mesoderm and spinal cord are necessary for the formation the latter. Our work has important implications for the study of cell-cell communication in development and how the bridge can be made between gene regulatory programs and complex multicellular developmental structures.