Project description:The mammalian embryos Caudal Lateral Epiblast (CLE) harbours bipotent progenitors, called Neural Mesodermal Progenitors (NMPs), that contribute to the spinal cord and the paraxial mesoderm throughout axial elongation. Here we performed a single cell analysis of different in vitro NMPs populations produced either from embryonic stem cells (ESCs) or epiblast stem cells (EpiSCs) and compared them to E8.25 CLE mouse embryos. In our analysis of this region our findings challenge the notion that NMPs can be defined by the exclusive coexpression of Sox2 and T at mRNA level. We analyse the in vitro NMP-like populations using a purpose-built Support Vector Machine (SVM) based on the embryo CLE and use it as a classification model to compare the in vivo and in vitro populations. Our results show that NMP differentiation from ESCs, leads to heterogeneous progenitor populations with few NMP-like cells, as defined by the SVM algorithm, whereas starting with EpiSCs, yields a high proportion of cells with the embryo NMP signature. We find that the population from which the Epi-NMPs are derived in culture contains a node-like population, which leads to suggest that this population probably maintains the expression of T in vitro and thereby a source of NMPs. In conclusion, differentiation of EpiSCs into NMPs reproduces events in vivo and suggests a sequence of events for the emergence of the NMPs population.

Project description:In the past decades, the paradigm of three germ layers formed by gastrulation has been modified by data suggesting an existence of neuromesodermal progenitors (NMPs) that arise during gastrulation and contribute to both spinal cord and adjacent paraxial mesoderm1-5. However, there lacks direct genetic lineage tracing evidence and functional assessment of NMPs in vivo. Here, we develop a dual recombinases-mediated genetic system to specifically trace and genetically ablate Brachyury+Sox2+ NMPs. Genetic lineage tracing results and single-cell RNA sequencing analysis show that NMPs contain three distinct uni-potent and bi-potent progenitor populations for progressive differentiation into neural and mesodermal fates. Genetic ablation of NMPs by diphtheria toxin reveals a critical role of NMPs in tail formation. This study provides in vivo genetic evidence for heterogeneity of NMPs in their cell fate determination and their functional role in developing embryos.

Project description:Human ES (H9) cells were directed towards a neuromesodermal progenitor-like cell state and these cells were then subsequently differentiated towards a neural cell fate. Human ES cells (H9) were differentiated into neuromesodermal progenitor-like cells by culturing in Neurobasal/1x N2/1x B27 medium (N2/B27) supplemented with 20 ng/ml bFgf and 3 μM CHIR99021 for 3 days and exposure to dual SMAD inhibition (dSMADi) (Noggin 50 ng/ml and the TGFb receptor type 1 inhibitor SB431542 10 μM) during day 3 (D3). Transcriptome analysis was then carried out following a selection procedure to enrich for NMP-like cells (sD3/NMP-like). This involved use of a hES (H9) cell line engineered with CRISPR-Cas9 to express GFP under the control of the endogenous Nkx1.2 promoter. At the end of day 3 cells were selected for high GFP expression, as high Nkx1.2 transcription is characteristic of NMP cell populations in mouse and chick embryos. These cells were then lysed and RNA extracted for RNASeq. Humans ES cells (H9) differentiated into NMP-like cells as above (without selection) were also allowed to develop further on day 4 (in the presence of dSMADi and Retinoic acid (RA) 100nM, in N2/B27) and then in RA alone until end of day 8 (D8). These cells were then lysed and RNA extracted for RNASeq.

Project description:Undifferentiated human embryonic stem cells (hESCs) were treated with WNT and FGF agonists for three days to generate NMP-like axial progenitors (NMPs).

Project description:Proteasomes are critical for peripheral nervous system (PNS) function. Here, we investigate mammalian PNS proteasomes and reveal the presence of the neuronal membrane proteasome (NMP). We show that specific inhibition of the NMP on distal nerve fibers innervating the mouse hind paw leads to reduction in mechanical and pain sensitivity. Investigating PNS NMPs we demonstrate their presence on the somata, proximal, and distal axons of a subset of dorsal root ganglion (DRG) neurons. Single-cell RNA sequencing experiments reveal that the NMP expressing DRGs are primarily MrgprA3+ and Cysltr2+. NMP inhibition in DRG cultures leads to cell autonomous and non-cell autonomous changes in Ca2+ signaling induced by KCl depolarization, ab-meATP, or the pruritogen histamine. Taken together, these data support a model whereby NMPs are expressed on a subset of somatosensory DRGs to modulate signaling between neurons of distinct sensory modalities and indicate the NMP as a potential target for controlling pain

Project description:Here, human pluripotent stem cells (including hiPSC and hESC) were induced to differentiate to mesenchymal stem cells (MSC) through the intermediate stage of neuromesoderm (NMP). We sequenced mRNA samples at different stages during NMP-MSC differentiation of human pluripotent stem cells to generate the gene expression profiles of these cells.

Project description:The spinal cord and mesodermal tissues of the trunk such as the vertebral column and skeletal musculature derive from neuro-mesodermal progenitors (NMPs). Sox2, Brachyury (T) and Tbx6 have been correlated with NMP potency and lineage choice, however, their exact role and interaction in these processes have not been revealed yet. Here we present a global analysis of NMPs and their descending lineages performed on purified cells from E8.5 wild-type and mutant embryos. We show that T, cooperatively with WNT signaling, controls the progenitor state and the switch towards the mesodermal fate. Sox2 acts antagonistically and promotes neural development. Tbx6 reinforces the mesodermal fate choice, represses the progenitor state and confers paraxial fate commitment. Our findings refine previous models and establish new concepts of the molecular principles of mammalian trunk development comprising NMP maintenance, lineage choice and mesoderm formation.

Project description:The spinal cord emerges from a niche of neuromesodermal progenitors (NMPs) formed and maintained by Wnt/FGF signals in the posterior end of the embryo. NMP-like cells can be generated from human pluripotent stem cells providing a promising source for spinal cord replacement therapies. However, these progenitors are often transient and unable to produce the full range of rostrocaudal spinal cord identities in vitro. Here we report the generation of NMP-derived pre-neural progenitors (PNPs). These PNPs maintain pre-spinal cord identity by co-expressing the transcription factors SOX2 and CDX2, while losing the mesodermal potential of NMPs by downregulating TBXT. They gradually adopt more posterior identity by activating collinear HOX gene expression, and in parallel undergo an epithelial-to-mesenchymal transition to give rise to neural crest (NC) cells with corresponding rostrocaudal identity.

Project description:Most human cancers demonstrate activated MAPK/ERK pathway signaling as a key tumor initiation step, but the immediate steps of further oncogenic progression are poorly understood due to a lack of appropriate models. Spinal cord differentiation follows caudal elongation in vertebrate embryos; both processes are regulated by a FGF8 gradient highest in neuromesodermal progenitors (NMP), where kinase effectors ERK1/2 maintain an undifferentiated state. FGF8/ERK signal attenuation is necessary for NMPs to progress to differentiation. We show that sustained ERK1/2 activity, using a constitutively active form of the kinase MEK1 (MEK1ca) in the chicken embryo, reproducibly provokes neopasia in the developing spinal cord. Transcriptomic data show that neoplasia not only relies on the maintenance of NMP gene expression, and the inhibition of genes expressed in the differentiating spinal cord, but also on a profound change in the transcriptional signature of the spinal cord cells leading to a complete loss of cell-type identity. MEK1ca expression in the developing spinal cord of the chicken embryo is therefore a tractable in vivo model to identify the critical factors fostering malignancy in ERK-induced tumorigenesis.

Project description:Retinoic acid (RA) signaling plays a major role in controlling several developmental processes in vertebrate embryos. RA repression of caudal Fgf8 has emerged as a crucial mechanism through which RA controls body axis extension, somitogenesis, and spinal cord neurogenesis. The role of RA in Fgf8 repression is supported by mechanistic studies demonstrating direct RA repression through a nearby RA response element that recruits NCOR in an RA-dependent manner. RA is also required for balanced neuromesodermal progenitor differentiation needed for coordinated generation of mesodermal progenitors for somites and neural progenitors for spinal cord. As many pathways are controlled by RA, we performed RNA-seq analysis comparing wild-type embryos with Aldh1a2 mutants that lack the ability to produce RA. This analysis identified a few hundred genes whose expression is significantly altered when RA is absent, thus providing candidate genes for further analysis to discover RA-regulated genes essential for development.