Project description:Differentiation proceeds along a continuum of increasingly fate-restricted intermediates, referred to as canalization. Canalization is essential for stabilizing cell fate, but mechanisms underlying robust canalization are unclear. Here we show that the BRG1/BRM-associated factor (BAF) chromatin remodeling complex ATPase gene Brm safeguards cell identity during directed cardiogenesis of mouse embryonic stem cells. Despite establishment of well-differentiated precardiac mesoderm, Brm-null cells predominantly became neural precursors, violating germ layer assignment. Trajectory inference showed sudden acquisition of non-mesodermal identity in Brm-null cells, consistent with a new transition state referred to as a saddle-node bifurcation. Mechanistically, loss of Brm prevented de novo accessibility of cardiac enhancers while increasing expression of neurogenic factor POU3F1, preventing expression of neural suppressor REST, and disrupting composition of BRG1 complexes. Brm mutant identity switch was overcome by increasing BMP4 levels during mesoderm induction. Mathematical modeling supports all our observations. In the mouse embryo, Brm deletion exacerbated mesoderm-deleted Brg1 mutant phenotypes, severely compromising cardiogenesis, unmasking an in vivo role for Brm. Our results reveal Brm as a compensable safeguard of the fidelity of mesoderm chromatin states, and support a model in which developmental canalization is not a rigid irreversible path, but a highly plastic trajectory.

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:Differentiation into diverse cell lineages requires orchestration of gene regulatory networks guiding cell fate choices. Genetic factors acting through changes in transcriptional levels can contribute to cardiovascular disease risk by impacting early stages of development and have cell type-specific effects. We set out to characterize lineage trajectory progression of subpopulations and identify potential disease-related genes by examining their expression changes in single cells during early stages of cardiac lineage specification. Using 43,168 single-cell transcriptomes, we developed novel classification and trajectory analysis methods to dissect cellular composition and gene networks across five discrete time points underlying lineage derivation of mesoderm, definitive endoderm, vascular endothelium, cardiac precursors, and definitive cell types that comprise cardiomyocytes and a previously unrecognized cardiac outflow tract population.

Project description:We sequenced mRNA from transverse slices of embryos from a variety of D. melanogaster mutants (bicoid over-expression, bicoid knockdown, hunchback knocdown, and zelda mutant) at the blastoderm stage to determine genome-wide patterns of gene expression. mRNA from transverse sections of single D. melanogaster embryos mutant for patterning TFs was sequenced.

Project description:Single cell technologies hold promise for resolving complex early developmental phenotypes. Here we define a novel Hedgehog (Hh)-Fibroblast Growth Factor (FGF) signaling axis for the formation of anterior mesoderm lineages during gastrulation. Single-cell transcriptome analysis of Hh-deficient mesoderm revealed selective deficits in anterior mesoderm populations—culminating in defects to anterior embryonic structures including the pharyngeal arches, heart, and anterior somites. Transcriptional profiling of Hh-deficient mesoderm during gastrulation revealed disruptions to both transcriptional patterning of the mesoderm and FGF signaling for mesoderm migration. Mesoderm-specific Fgf4/Fgf8 double mutants recapitulated anterior mesoderm defects and Hh-dependent GLI transcription factors modulated enhancers at FGF gene loci.  Cellular migration defects during gastrulation induced by Hh pathway antagonism were mitigated by FGF4 protein. These findings implicate a multicomponent signaling hierarchy activated by Hh ligands from the embryonic node and executed by FGF signals in nascent mesoderm to control anterior mesoderm patterning.

Project description:The node and notochord are important signaling centers organizing dorso-ventral patterning of cells arising from neuro-mesodermal progenitors forming the embryonic body anlage. Due to the scarcity of notochordal progenitors and notochord cells, a comprehensive identification of regulatory elements driving notochord-specific gene expression has been lacking. Here we have used ATAC-seq analysis of FACS-purified notochordal cells from TS12-13 mouse embryos to identify 8921 putative enhancers of notochordal cells. In addition, we established a new model for generating notochordal cells in culture, and identified 3728 enhancers occupied by the essential notochordal regulators Brachyury (T) and/or Foxa2. We describe the regulatory landscape of the T locus comprising 8 putative enhancers occupied by these factors and confirmed the regulatory activity of 3 of these elements. Moreover, we characterized one new notochord enhancer, termed TNE2, in embryos. TNE2 complements the loss of TNE in the trunk notochord, and is essential for notochordal cell proliferation and differentiation in the tail. Our data demonstrate the essential role of Foxa2 in the choice of T expressing cells between the notochordal fate and the NMP/mesodermal trajectory

Project description:Eyal-Giladi and Kochav stage X (EGK.X) blastoderm mostly consists undifferentiated progenitor (pluripotent) cells that have the potency to differentiate into all cell types. Analyzing the transcriptional programs of blastoderm is critical to understand the molecular mechanisms that underlie the developmental fate of early embryos, and practical application of blastoderm-derived pluripotent cells, including ESC. Primordial germ cells (PGC) are also undifferentiated progenitor cells that later differentiate into male and female germ cells. Analyzing the transcriptional programs of PGC is critical to understand the molecular mechanisms that underlie the developmental fate of early germ cells, and practical application of PGC in generating transgenic chickens. Therefore, we performed whole-transcriptome sequencing (WTS) in the chicken EGK.X blastoderm and PGCs together with the chicken embryonic fibroblasts (CEF, as a reference sample). CEF are differentiated and an abundant somatic cells. The generated WTS data of CEF, EGK.X blastoderm and PGC are rich resources to utilize for various focused research. As a first focused research, we utilized the generated WTS data for analyzing the expression profiling of DNA repair and apoptosis pathway genes in EGK.X blastoderm and PGC compared with CEF. DNA is the fundamental unit of inheritance and is susceptible to damage by various exogenous and endogenous sources. When the DNA is damaged, the cell sense the nature of damage through multiple surveillance mechanisms and select an appropriate DNA repair pathway to repair the damage and avoid passing the damage to a progeny of cells. When the cell fails to repair DNA damage, cell cycle progression is halted and apoptosis is initiated. Despite several genes are involved in five major DNA repair pathways and two major apoptosis pathways, a comprehensive understanding on the expression of those genes are not well-understood in chicken tissues. Through WTS analysis in CEF, stage X blastoderm and PGC, we identified that most of the DNA repair pathway genes were expressed more high in blastoderm and high in PGC than CEF. At the other hand, most of the apoptosis pathway genes were expressed low in blastoderm and PGC than CEF.

Project description:Single-cell RNA-seq reveals that Polycomb repressive complex 2 (PRC2) maintains naïve pluripotency and restricts an intrinsic capacity of pre-implantation pluripotent stem cells to give rise to trophectoderm and mesoderm lineages. Inhibition of PRC2 forces naïve hESC into an ‘activated’ state through which differentiation into either trophectoderm or mesoderm lineages is triggered. This trajectory is distinct from embryonic lineage specification out of the post-implantation pluripotent state, hence PRC2-mediated repression provides a highly adaptive mechanism to restrict lineage potential during early human development.

Project description:During cerebellar development, the main portion of the cerebellar plate neuroepithelium (NE) gives birth to Purkinje cells and interneurons, while the germinal zone at its dorsal edge, called the rhombic lip (RL), generates granule cells and cerebellar nuclei neurons. However, it remains elusive how these components work together to generate the intricate structure of the cerebellar anlage. In this study, we found that a polarized cerebellar anlage structure self-organizes in three-dimensional (3D) human ES cell (hESC) culture. This NE is capable of differentiating into electrophysiologically functional Purkinje cells. The addition of FGF19 promotes spontaneous generation of dorsoventrally polarized NE structures containing cerebellar and basal plates. Furthermore, further addition of SDF1 promoted the generation of stratified cerebellar plate NE with RL-like germinal zones self-forming at the edge. Thus, hESC-derived cerebellar progenitors exhibit substantial self-organizing potential for generating a polarized structure reminiscent of the early human cerebellar anlage at the first trimester. Examination of mRNA profile in two different treated human ES cells .

Project description:Through high-resolution single cell and genetic lineage/clonal analyses, we show an unsuspected clonal relationship between extraembryonic mesoderm and cardiac lineages.  Single-cell transcriptomics and trajectory analyses uncovered two mesodermal progenitor sources contributing to left ventricle cardiomyocytes, one embryonic and the other with an extraembryonic gene expression signature.  Additional lineage-tracing studies revealed that the extraembryonic-related progenitors reside at the embryonic-extraembryonic interface in gastrulating embryos, and produce distinct cell types forming the pericardium, septum transversum, epicardium, dorsolateral regions of the left ventricle and atrioventricular canal myocardium, and extraembryonic mesoderm.  Clonal analyses demonstrated that these progenitors are multipotent, giving rise to not only cardiomyocytes and serosal mesothelial cell types but also, remarkably, extraembryonic mesoderm.