Project description:Ewing sarcoma family of tumors (ESFT) are aggressive bone and soft tissue tumors of unknown cellular origin. Most ESFT express EWS-FLI1, a chimeric protein which functions as a growth-promoting oncogene in ESFT but is toxic to most normal cells. A major difficulty in understanding EWS-FLI1 function has been the lack of an adequate model in which to study EWS-FLI1-induced transformation. Although the cell of origin of ESFT remains elusive, both mesenchymal (MSC) and neural crest (NCSC) have been implicated. We recently developed the tools to generate NCSC from human embryonic stem cells (hNCSC). In the current study we used this model to test the hypothesis that neural crest-derived stem cells are the cells of origin of ESFT and to evaluate the consequences of EWS-FLI1 expression on human neural crest biology. hNCSC transduced with an EWS-FLI1 lentivirus tolerated expression of the oncoprotein. Moreover, EWS-FLI1-transduced hNCSC continued to proliferate and maintain EWS-FLI1 expression in culture for several weeks after transduction. Affymetrix HuEx 1.0 expression profiling of hNCSC cells five days post-transduction with EWS-FLI1 demonstrated the expected induction and repression of well-established EWS-FLI1 targets and also identified numerous other novel EWS-FLI1-regulated genes that are likely to be cell-type and situation specific. In particular, the EWS-FLI1 repressive signature was found to be highly context dependent. Moreover, while control vector transduced cells displayed an MSC-like phenotype, EWS-FLI1-transduced cells maintained a NCSC-like phenotype and genetic profiling revealed reprogramming towards a more pluriopotent, neuroectodermal state. Finally, EWS-FLI1 expressing cells upregulated expression of the polycomb proteins BMI-1 and EZH2. These data implicate neural crest-derived cells in the origin of ESFT and suggest that EWS-FLI1 enables malignant transformation by inducing maintenance of a multipotent, NCSC-state through deregulation of polycomb genes. 3 replicate samples for 4 different stem cell populations were analyzed by HuEx arrays. The 4 sample types were adult human bone marrow-derived mesenchymal stem cells, human embryonic stem cell-derived nueral crest stem cells (hNCSC), control vector-transduced hNCSC-derived mesenchymal stem cells (NC-MSC), and EWS-FLI1-transduced hNCSC-derived mesenchymal stem cells (NC-MSC EF). Control and EWS-FLI1 transduced NC-MSC were isolated 5 days after lentiviral transduction. Transcript level expression data was compared among the different populations to determine differences and similarities between NCSC, BM-MSC and NC-MSC with/without EWS-FLI1 expression. These data were used to identify EWS-FLI1 targets in NC-MSC and to characterize the genetic changes that occur in NCSC as they generate NC-MSC progeny.

Project description:Neural crest (NC) cells contribute to the development of many complex tissues. The abnormal development of NC cells accounts for a number of congenital birth defects. Generating NC cells, and more specifically NC subpopulations such as cranial, cardiac, and trunk NC cells from human induced pluripotent stem (iPS) cells and human embryonic stem (ES) cells presents a valuable tool to model and study human NC development and disease. Here we provide a robust, efficient, and reproducible protocol for the differentiation of human iPS and ES cells into NC cells. The protocol has been validated in multiple human pluripotent stem cell lines and yields relatively pure NC cell populations in eight days. The resulting cells can be propagated and retain NC marker expression over multiple passages. The NC cells show proper cell specification and can develop into NC-derived cell lineages including smooth muscle cells, peripheral neurons, and Schwann cells. Additionally, the NC cells are functional and migrate to appropriate chemoattractants such as SDF-1, Fgf8b, BMP2, and Wnt3a. Importantly, this method generates all NC subpopulations (cranial, cardiac, and trunk) providing a great advantage to readily available NC differentiation methods. Neural crest cells derived from human induced pluripotent stem cells were profiled using Affymetrix Gene 1.0 arrays to identify differential gene expression changes and alternative exons from the open-source software AltAnalyze. An FDR adjusted emperical Bayes moderated t-test p < 0.05 was used to identify differentially expressed Ensembl genes and GO-Elite used to identify biologically relevant, Ontology, pathway and gene-set categories. Alternative exons were obtained using the FIRMA analysis option and default thresholds. Other array neural crest array and RNA-Seq dataset were compared to this to identify common and distinct regulatory mechanisms.

Project description:High-risk 11q deleted neuroblastomas (NBs) typically display an undifferentiated/poorly differentiated morphology. NB is thought to develop from Schwann cell precursors (SCPs) and un-differentiated neural crest derived cells (NCC). It is therefore vital to understand the mechanisms involved in the block of differentiation. We showed that an important and novel role for oncogenic ALK-ERK1/2-SP1 signaling may be the maintenance of an undifferentiated state of transformed NC-derived progenitors that is achieved by repression of DLG2, a tumor suppressor in NB. DLG2 is expressed in the ‘bridge signature’ that represents the transcriptional transition state when neural crest cells or Schwann Cell Precursors (SCP) become chromaffin cells of the adrenal gland. The importance of SP1 and DLG2 in this process is highlighted by our findings that restoring DLG2 expression spontaneously drives NB differentiation. Further, genetic analysis of high-risk 11q deletion NB patient identified genetic lesions in the DLG2 gene, Our data also suggest that further exploration of other ‘bridge genes’ may help to better understand the mechanisms underlying the differentiation of NC-derived progenitors and their contribution to NB.

Project description:Neural crest cells are a transient embryonic population, hence are neither present after bith and nor are they readily accesible for analysis. Therefore, little is known about the genetic networks that regulate NC especification, delamitation and migration from the dorsal neural tube to their final destination along the embryo. Here we have developed a novel resource for lineage tracing and for the isolation of neural crest cells in the chick embryo, enabling us to perform a genome-wide expression screen in neural crest progenitors versus neuroepithelial cells.

Project description:In this study, we propose a novel method for inducing neuronal cells by briefly exposing them to small-molecule cocktails in a step-by-step manner. Global gene expression analysis with immunohistochemical staining and calcium flux assays reveal the generation of neurons from mouse embryonic fibroblasts (MEFs). In addition, time-lapse imaging of neural precursor-specific enhancer expression and global gene expression analyses show that the neurons are generated by passing through a neural crest-like precursor stage. Consistent with these results, the neural crest-like cells are able to differentiate into neural crest lineage cells, such as sympathetic neurons, adipocytes, osteocytes, and smooth muscle cells. Therefore, these results indicate that brief exposure to chemical compounds could expand and induce a substantial multipotent cell population without viral transduction.

Project description:Neural crest cells are multipotent cells that delaminate from the neuroepithelium, migrating throughout the embryo. Aberrant migration causes developmental defects. Animal models are improving our understanding of neural crest anomalies, but in vivo migration behaviours are poorly understood. Here, we demonstrate that murine neural crest cells display actin-based lamellipodia and filopodia in vivo. Using neural crest-specific knockouts or inhibitors, we show that the serine-threonine kinase Glycogen Synthase Kinase-3 (GSK3), and the cytoskeletal regulator Lamellipodin (Lpd), are required for lamellipodia formation whilst preventing focal adhesion maturation. Lpd is a novel substrate of GSK3 and phosphorylation of Lpd favours interactions with the Scar/WAVE complex (lamellipodia formation) at the expense of VASP and Mena interactions (adhesion maturation and filopodia formation). This improved understanding of cytoskeletal regulation in mammalian neural crest migration has general implications for neural crest anomalies and cancer.

Project description:The neural crest (NC) is a transient embryonic stem cell population characterised by its multipotency and broad developmental potential. Here, we perform NC-specific transcriptional and epigenomic profiling of foxd3-mutant versus wild-type cells in vivo to define the gene regulatory circuits controlling NC specification. Together with global binding analysis obtained by foxd3 biotin-ChIP and single cell profiles of foxd3-expressing premigratory NC, our analysis shows that during early steps of NC formation, foxd3 acts globally as a pioneer factor to prime the onset of genes regulating NC specification and migration by re-arranging the chromatin landscape, opening cis-regulatory elements and reshuffling nucleosomes. Strikingly, foxd3 then gradually switches from an activator to its previously well-described role as a transcriptional repressor. Taken together, these results demonstrate that foxd3 acts bimodally in the neural crest as a switch from ‘permissive’ to ‘repressive’ nucleosome/chromatin organisation to maintain multipotency and define cell fates.

Project description:Neural crest cells (NC cells) are multipotent cells that emerge from the dorsal region of a fusing neural tube and migrate throughout the developing embryo. Due to their multipotency and divergent roles during embryogenesis, the generation and differentiation of NC cells should be elucidated in more detail. However, difficulties have been associated with isolating and manipulating NC cells for investigation because a limited number of NC cells are generated in a short period of embryogenesis. To overcome this issue, we attempted to directly convert mouse fibroblasts into NC cells using transcription factors specifically expressed in NC cells. We analyzed the molecular profiles of NC cells and neural tube cells in 9.5-day mouse embryos, and identified the transcription factors that were strongly expressed in NC cells. Among these transcription factors, Sox10 together with c-Myc and Klf4 directly converted mouse fibroblasts into NC cells. The converted NC cells differentiated into neurons, glial cells, smooth muscle cells, adipocytes, and osteoblasts, exhibiting differentiation abilities similar to those of in vivo NC cells. They also displayed a self-renewal ability while maintaining their differentiation ability. In in ovo transplantation, the converted NC cells migrated along NC cell migration pathways. Therefore, directly converted NC cells can contribute to the progression of NC cell studies.

Project description:Melanocytes are pigment-producing cells of neural crest origin responsible for protecting the skin against UV-irradiation. Melanocyte dysfunction leads to pigmentation defects including albinism, vitiligo, and piebaldism and is a key feature of systemic pathologies such as Hermansky-Pudlak (HP) and Chediak-Higashi (CH) Syndromes. Pluripotent stem cell technology offers a novel approach for studying human melanocyte development and disease. Here we report that timed exposure to activators of WNT, BMP and EDN3 signaling triggers the sequential induction of neural crest and melanocyte precursor fates under dual-SMAD inhibition conditions. Using a SOX10::GFP hESC reporter line, we demonstrate that the temporal onset of WNT activation is particularly critical for human neural crest induction. Surprisingly, suppression of BMP signaling does reduce neural crest yield. Subsequent differentiation of hESC-derived melanocyte precursors under defined conditions yields pure populations of pigmented cells matching the molecular and functional properties of adult melanocytes. Melanocytes from patient-specific iPSCs faithfully reproduce the ultrastructural features of the HP- and CH-specific pigmentation defects with minimal variability across lines. Our data define a highly specific requirement for WNT signaling during neural crest induction and enable the generation of pure populations of hiPSC-derived melanocytes for faithful modeling of human pigmentation disorders. Total RNA obtained from a timecourse of Dual SMAD Inhibition (DSi), Neural Crest (NC), and Melanocyte (BE) differentiation of human embryonic stem cells in triplicate.

Project description:Recent studies suggest that malignant melanoma heterogeneity includes subpopulations of cells with features of multipotent neural crest (NC) cells. Zebrafish and mouse models have shown that reactivation of neural crest-specific pathways determines the invasiveness of melanoma cells. In this study, we show that the neural crest-associated transcription factor FOXD1 plays a key role in invasion and migration capacity of metastatic melanomas both in vivo and in vitro. Gene expression profiling analysis identified on one hand, an upregulation of FOXD1 in NC and melanoma cells, and on the other hand, a downregulation of several genes related to cell invasion in FOXD1 knockdown cells, including MMP9 and RAC1B. Furthermore, we demonstrate that knockdown of RAC1B a tumor-specific isoform of RAC1, significantly impaired cell migration and invasion in melanoma and could abrogate enhanced invasiveness induced by FOXD1 overexpression. We conclude that FOXD1 may influence invasion and migration via indirect regulation of MMP9 and RAC1B alternative splicing in melanoma cells.