Project description:Mammals have four genomic copies of an ancestral Hox cluster, with a total of 39 genes. While gene inactivation approaches and full cluster deletions have revealed their critical functions during early development, the effect of removing all Hox function has remained elusive due to both biological and technological challenges. We have used mouse gastruloids, an ES cells-derived embryo model where Hox genes are properly activated in time and space, to assess the effect of their complete absence. We report that gastruloids lacking Hox function can still elongate and reach a general shape resembling their control counterparts, with a well-established AP polarity. However, unlike controls, they fail to produce any endoderm and are unable to properly segment their presomitic mesoderm into persistent somite-like structures. Instead, they produce a type of mesoderm with a more anterior identity. We thus propose that, in this system at least, HOX proteins are necessary to posteriorize an existing anterior ‘ground-state’ structure, in part by promoting and/or maintaining the epithelialization of cellular condensations. Multiomes analysis revealed range of modifications in chromatin accessibility in the absence of any HOX proteins, involving in particular variations in the binding of the co-factor PBX1. In contrast, neuro-mesodermal progenitor (NMP) cells are not overtly affected in mutant gastruloids, even though they normally initiate strong Hox gene transcription, suggesting that these cells are used as vehicles to translate a temporal sequence of activation into an AP colinear transcript distribution, which becomes functional at a later stage only.

Project description:Mammals have four genomic copies of an ancestral Hox cluster, with a total of 39 genes. While gene inactivation approaches and full cluster deletions have revealed their critical functions during early development, the effect of removing all Hox function has remained elusive due to both biological and technological challenges. We have used mouse gastruloids, an ES cells-derived embryo model where Hox genes are properly activated in time and space, to assess the effect of their complete absence. We report that gastruloids lacking Hox function can still elongate and reach a general shape resembling their control counterparts, with a well-established AP polarity. However, unlike controls, they fail to produce any endoderm and are unable to properly segment their presomitic mesoderm into persistent somite-like structures. Instead, they produce a type of mesoderm with a more anterior identity. We thus propose that, in this system at least, HOX proteins are necessary to posteriorize an existing anterior ‘ground-state’ structure, in part by promoting and/or maintaining the epithelialization of cellular condensations. Multiomes analysis revealed range of modifications in chromatin accessibility in the absence of any HOX proteins, involving in particular variations in the binding of the co-factor PBX1. In contrast, neuro-mesodermal progenitor (NMP) cells are not overtly affected in mutant gastruloids, even though they normally initiate strong Hox gene transcription, suggesting that these cells are used as vehicles to translate a temporal sequence of activation into an AP colinear transcript distribution, which becomes functional at a later stage only.

Project description:Mammals have four genomic copies of an ancestral Hox cluster, with a total of 39 genes. While gene inactivation approaches and full cluster deletions have revealed their critical functions during early development, the effect of removing all Hox function has remained elusive due to both biological and technological challenges. We have used mouse gastruloids, an ES cells-derived embryo model where Hox genes are properly activated in time and space, to assess the effect of their complete absence. We report that gastruloids lacking Hox function can still elongate and reach a general shape resembling their control counterparts, with a well-established AP polarity. However, unlike controls, they fail to produce any endoderm and are unable to properly segment their presomitic mesoderm into persistent somite-like structures. Instead, they produce a type of mesoderm with a more anterior identity. We thus propose that, in this system at least, HOX proteins are necessary to posteriorize an existing anterior ‘ground-state’ structure, in part by promoting and/or maintaining the epithelialization of cellular condensations. Multiomes analysis revealed range of modifications in chromatin accessibility in the absence of any HOX proteins, involving in particular variations in the binding of the co-factor PBX1. In contrast, neuro-mesodermal progenitor (NMP) cells are not overtly affected in mutant gastruloids, even though they normally initiate strong Hox gene transcription, suggesting that these cells are used as vehicles to translate a temporal sequence of activation into an AP colinear transcript distribution, which becomes functional at a later stage only.

Project description:Mammals have four genomic copies of an ancestral Hox cluster, with a total of 39 genes. While gene inactivation approaches and full cluster deletions have revealed their critical functions during early development, the effect of removing all Hox function has remained elusive due to both biological and technological challenges. We have used mouse gastruloids, an ES cells-derived embryo model where Hox genes are properly activated in time and space, to assess the effect of their complete absence. We report that gastruloids lacking Hox function can still elongate and reach a general shape resembling their control counterparts, with a well-established AP polarity. However, unlike controls, they fail to produce any endoderm and are unable to properly segment their presomitic mesoderm into persistent somite-like structures. Instead, they produce a type of mesoderm with a more anterior identity. We thus propose that, in this system at least, HOX proteins are necessary to posteriorize an existing anterior ‘ground-state’ structure, in part by promoting and/or maintaining the epithelialization of cellular condensations. Multiomes analysis revealed range of modifications in chromatin accessibility in the absence of any HOX proteins, involving in particular variations in the binding of the co-factor PBX1. In contrast, neuro-mesodermal progenitor (NMP) cells are not overtly affected in mutant gastruloids, even though they normally initiate strong Hox gene transcription, suggesting that these cells are used as vehicles to translate a temporal sequence of activation into an AP colinear transcript distribution, which becomes functional at a later stage only.

Project description:Human gastruloids are a powerful class of stem cell-derived models that recapitulate key features of early embryonic development, including symmetry breaking and the emergence of three germ layers. However, they lack anterior embryonic structures and coordinated axial organization. To address this limitation, we pre-patterned human pluripotent stem cells (hPSCs) by exposing them to either anterior (FGF2) or posterior (CHIR99021 [CHIR] & retinoic acid [RA]) cues. Upon mixing, these dual-patterned hPSCs interacted and self-organized into elongated structures with both anterior and posterior features—which we term anterior-posterior (AP) human gastruloids. Anteriorly pre-treated cells robustly intercalated into posteriorly pre-treated cells, collectively giving rise to a continuum of neural tissues—including a brain-like domain, a neural tube-like structure, and neuro-mesodermal progenitors (NMPs)—with segmented somites arrayed bilaterally. Single cell RNA sequencing (scRNA-seq) revealed that human AP gastruloids contain cell types resembling the midbrain-hindbrain boundary (MHB), regionalized hindbrain structures (i.e. rhombomeres 1–8), regionalized neural crest (i.e. cranial, vagal, trunk) and head mesoderm. Transcriptomic comparisons to primate embryos revealed that human AP gastruloids most closely resemble Carnegie stage 11 (CS11) embryos. While they lack a notochord and full dorsal-ventral polarity, human AP gastruloids recapitulate key spatial and temporal features of early neurulation and somitogenesis. Perturbation of folic acid metabolism or rho-associated kinase (ROCK) signaling induced spinal cord defects, phenocopying aspects of spina bifida and other neural tube defects, highlighting this model’s potential for studying congenital disorders. AP gastruloids may serve as a simple, robust, scalable platform for modeling coordinated human AP body axis development. More broadly, our results suggest that controlled interactions between differentially prepatterned progenitors can initiate self-organization of complex body axis features. The “pattern-and-mix” strategy may serve as a generalizable framework for assembling spatially organized stem cell models of mammalian development.

Project description:Cardiopharyngeal mesoderm contributes to the formation of the heart and head muscles. However, the mechanisms governing cardiopharyngeal mesoderm specification remain unclear. Indeed, there is a lack of an in vitro model replicating the differentiation of both heart and head muscles to study these mechanisms. Such models are required to allow live-imaging and high throughput genetic and drug screening. Here, we show that the formation of self-organizing or pseudo-embryos from mouse embryonic stem cells (mESCs), also called gastruloids, reproduces cardiopharyngeal mesoderm specification towards cardiac and skeletal muscle lineages. By conducting a comprehensive temporal analysis of cardiopharyngeal mesoderm establishment and differentiation in gastruloids and comparing it to mouse embryos, we present the first evidence for skeletal myogenesis in gastruloids. By inferring lineage trajectories from the gastruloids single-cell transcriptomic data, we further suggest that heart and head muscles formed in gastruloids derive from cardiopharyngeal mesoderm progenitors. We identify different subpopulations of cardiomyocytes and skeletal muscles, which most likely correspond to different states of myogenesis with “head-like” and “trunk-like” skeletal myoblasts. These findings unveil the potential of mESC-derived gastruloids to undergo specification into both cardiac and skeletal muscle lineages, allowing the investigation of the mechanisms of cardiopharyngeal mesoderm differentiation in development and how this could be affected in congenital diseases.

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:In vertebrates, body axis elongation is fuelled by bipotent neuromesodermal progenitors (NMPs), which support the development of both spinal cord and paraxial mesoderm (PM). HOX transcription factors have been historically implicated in axial elongation, with their sequential activation playing a fundamental role in timing PM development. PBX1 and PBX2 are obligate anterior HOX cofactors, and therefore they represent prominent candidates for controlling the distinct response to individual HOX factors. To pinpoint the role of PBX proteins in the development of pre-somitic mesoderm (PSM), wild-type (WT) and Pbx1/Pbx2 double-mutant (Pbx1/2-DKO) EpiSCs were differentiated in vitro to PSM. Single cells from different time-points (WT: EpiSCs, 6 hours, 12 hours, 24 hours, 36 hours, 48 hours; Pbx1/2-DKO: 24 hours, 36 hours, 48 hours) were FACS-sorted into 384-well capture plates, and single-cell RNA-sequencing was performed using MARS-seq (Jaitin D.A. et al., Science, 343, 776-779 (2014)). Two wells were left empty in each plate, as a no-cell control during data analysis.

Project description:In vertebrates, body axis elongation is fuelled by bipotent neuromesodermal progenitors (NMPs), which support the development of both spinal cord and paraxial mesoderm (PM). HOX transcription factors have been historically implicated in axial elongation, with their sequential activation playing a fundamental role in timing PM development. PBX1 and PBX2 are obligate anterior HOX cofactors, and therefore they represent prominent candidates for controlling the distinct response to individual HOX factors. In our work, we have demonstrated that PBX proteins play a fundamental role in promoting the expression of PM genes, including the master regulator Mesogenin1 (Msgn1). To address the role of PBX proteins in PM differentiation, RNA-seq was performed on wild-type (WT) and Pbx1/Pbx2 double-knockout (Pbx1/2-DKO) EpiSCs differentiated in vitro to pre-somitic mesoderm (PSM) at different time-points (12 hours and 24 hours). To establish the direct transcriptional regulation of Msgn1 by PBX/HOX, we employed the CRISPR/Cas9 technology to generate lines carrying base-pair substitutions on the Msgn1 promoter (pMsgn1-mut) that abrogate the recruitment of PBX/HOX complexes, and we performed RNA-seq of pMsgn1-mut EpiSCs differentiated in vitro to PSM at 24 hours. All differentiation experiments were performed in biological triplicates with WT and Pbx1/2-DKO lines, and in biological duplicates with pMsgn1-mut lines.

Project description:In vertebrates, body axis elongation is fuelled by bipotent neuromesodermal progenitors (NMPs), which support the development of both spinal cord and paraxial mesoderm (PM). WNT signalling sustains both NMP expansion and PM differentiation, but the mechanism by which it distinguishes between these alternative fates is unknown. HOX transcription factors have been historically implicated in axial elongation, with their sequential activation playing a fundamental role in timing PM development. PBX1 and PBX2 are obligate anterior HOX cofactors, and therefore they represent prominent candidates for controlling the distinct response to individual HOX factors. In our work, we have demonstrated that PBX/HOX complexes establish a permissive chromatin landscape for de novo recruitment of the WNT-effector LEF1 on PM genes, including the master regulator Mesogenin1 (Msgn1). To assess the PBX-dependent changes in chromatin accessibility during PM differentiation, we performed ATAC-seq of wild-type (WT) and Pbx1/Pbx2 double-knockout (Pbx1/2-DKO) EpiSCs differentiated in vitro to pre-somitic mesoderm (PSM) at different time-points (EpiSCs, 6 hours, 12 hours, 24 hours, 36 hours, 48 hours). To assess the direct consequence of PBX/HOX binding on chromatin accessibility, we employed the CRISPR/Cas9 technology to generate lines carrying base-pair substitutions on the Msgn1 promoter (pMsgn1-mut) that abrogate the recruitment of PBX/HOX complexes, and we performed ATAC-seq of pMsgn1-mut EpiSCs differentiated in vitro to PSM at different time-points (12 hours, 24 hours, 36 hours, 48 hours).