Project description:TGFβ superfamily signaling regulates the state of human stem cell pluripotency and competency to create telencephalic organoids

Project description:Use of single-cell transcriptomics to test early HD selective vulnerability by comparing CTRL and HD telencephalic organoids at day 45 and 120 of differentiation. To test the influence and the interactions between healthy and HD cells, chimeric organoids composed of CTRL and HD cells juxtaposed within the same organoid were grown and analyzed by scRNAseq at day 120.

Project description:Long-term culture of human telencephalic organoids cultured in the presence or absence of exogenous ECM. To evaluate how ECM supplementation influences organoid development, we supplied exogenous ECM in the form of Matrigel at the beginning of neuroepithelialisation (day 10, D10), either as a solid droplet that provides long-term exposure to a polymerized network of ECM proteins (droplet embedding - condition "drop" in the metadata table), or transiently dissolved in the culture medium (concentration of 2%V/V ) from D10 to D13 (liquid embedding - "liq"). These protocols were compared to one without exposure to exogenous ECM ("no"). Organoids were processed at 120 days of culture, when mature cortical tissue is present.

Project description:Human telencephalic organoid development in the presence and absence of exogenous extracellular matrix

Project description:Comparison of gene expresion profile of 4 SC clones and 4 SI clones at different time points defined a stabilization competency signiture required for successful reprogramming mRNA profilling 4 SI clones at 5 time points, 4 SC clones at 6 time points, and 3 feeder samples.

Project description:Human telencephalon is an evolutionary advanced brain structure associated with many uniquely human behaviors and disorders. However, cell lineages and molecular pathways implicated in human telencephalic development remains largely unknown. We generated human telencephalic organoids from stem cell-derived single neural rosettes (SNRs) and investigated telencephalic development under normal and pathological conditions. SNR-derived organoids contained pallial and subpallial neural progenitors (NPs), excitatory and inhibitory neurons, as well as macroglial and periendothelial cells, and demonstrated predictable organization and cytoarchitecture. We comprehensively characterized the properties of neurons in SNR-derived organoids and identified transcriptional programs associated with the specification of+B50:B51 excitatory and inhibitory lineages from a common pool of NPs early in telencephalic development. We also demonstrated that neurons in organoids with a hemizygous deletion of an autism- and intellectual disability associated gene SHANK3 exhibit intrinsic and excitatory synaptic deficits associated with impaired expression of clustered protocadherins. Collectively, this study validates SNR-derived organoids as a reliable new model for studying human telencephalic development and identifies novel molecular pathways disrupted by SHANK3 hemizygosity in human telencephalic tissue.

Project description:Human telencephalon is an evolutionary advanced brain structure associated with many uniquely human behaviors and disorders. However, cell lineages and molecular pathways implicated in human telencephalic development remains largely unknown. We generated human telencephalic organoids from stem cell-derived single neural rosettes (SNRs) and investigated telencephalic development under normal and pathological conditions. SNR-derived organoids contained pallial and subpallial neural progenitors (NPs), excitatory and inhibitory neurons, as well as macroglial and periendothelial cells, and demonstrated predictable organization and cytoarchitecture. We comprehensively characterized the properties of neurons in SNR-derived organoids and identified transcriptional programs associated with the specification of excitatory and inhibitory lineages from a common pool of NPs early in telencephalic development. We also demonstrated that neurons in organoids with a hemizygous deletion of an autism- and intellectual disability associated gene SHANK3 exhibit intrinsic and excitatory synaptic deficits associated with impaired expression of clustered protocadherins. Collectively, this study validates SNR-derived organoids as a reliable new model for studying human telencephalic development and identifies novel molecular pathways disrupted by SHANK3 hemizygosity in human telencephalic tissue.

Project description:Human telencephalon is an evolutionary advanced brain structure associated with many uniquely human behaviors and disorders. However, cell lineages and molecular pathways implicated in human telencephalic development remains largely unknown. We generated human telencephalic organoids from stem cell-derived single neural rosettes (SNRs) and investigated telencephalic development under normal and pathological conditions. SNR-derived organoids contained pallial and subpallial neural progenitors (NPs), excitatory and inhibitory neurons, as well as macroglial and periendothelial cells, and demonstrated predictable organization and cytoarchitecture. We comprehensively characterized the properties of neurons in SNR-derived organoids and identified transcriptional programs associated with the specification of+B50:B51 excitatory and inhibitory lineages from a common pool of NPs early in telencephalic development. We also demonstrated that neurons in organoids with a hemizygous deletion of an autism- and intellectual disability associated gene SHANK3 exhibit intrinsic and excitatory synaptic deficits associated with impaired expression of clustered protocadherins. Collectively, this study validates SNR-derived organoids as a reliable new model for studying human telencephalic development and identifies novel molecular pathways disrupted by SHANK3 hemizygosity in human telencephalic tissue.

Project description:Underdeveloped lungs are the primary cause of death in premature infants, however, little is known about stem and progenitor cell maintenance during human lung development. In this study, we have identified that FGF7, Retinoic Acid and CHIR-99021, a small molecule that inhibits GSK3 to activate Wnt signaling, support in vitro maintenance of primary human fetal lung bud tip progenitor cells in a progenitor state. Furthermore, these factors are sufficient to derive a population of human bud tip-like progenitor cells in 3D organoid structures from human pluripotent stem cells (hPSC). Functional studies showed that hPSC-derived bud tip progenitor organoids do not contain any mesenchymal cell types, maintain multilineage potential in vitro and are able to engraft into the airways of injured mice and respond to systemic factors. We performed RNA-sequencing to assess the degree of similarity in global gene expression profiles between the full human fetal lung (59-127 days gestation), isolated human fetal bud tip progenitors, organoids grown from primary fetal bud tip progenitors, and hPSC-derived bud tip organoids. Results showed that hPSC-derived organoids have molecular profiles similar to organoids generated from primary human fetal lung tissue. Gene expression differences between hPSC-derived bud tip organoids and fetal progenitor organoids may be related to the presence of contaminating mesenchymal cells in primary cultures. hPSC-derived bud tip organoids are generated from a well-defined human cell sources, offering a distinct advantage over rare primary tissue as a means to study human specific lung development, homeostasis and disease.<br>Sample Nomenclature - Description<br> -------------------------------------------------------------------------<br> Peripheral fetal lung the distal/peripheral portion of the fetal lung (i.e., distal 0.5 cm) was excised from the rest of the lung using a scalpel. This includes all components of the lung (e.g., epithelial, mesenchymal, vascular). <br>Isolated fetal bud tip the bud peripheral portion of the fetal lung was excised with a scalpel and subjected to enzymatic digestion and microdissection. The epithelium was dissected and separated from the mesenchyme, but a small amount of associated mesenchyme likely remained. <br>Fetal progenitor organoid 3D organoid structures that arose from culturing isolated fetal epithelial bud tips. <br>Foregut spheroid 3D foregut endoderm structure as described in Dye et al. (2015). Gives rise to patterned lung organoid (PLO) when grown in 3F medium. <br> Patterned lung organoid (PLO) lung organoids that were generated by differentiating hPSCs, as described throughout the manuscript. <br> Bud tip organoid organoids derived from PLOs, enriched for SOX2/SOX9 co-expressing cells, and grown/passaged in 3F medium.

Project description:Signaling mechanisms mediated by the Transforming Growth Factor-beta (TGF-beta) superfamily regulate a variety of developmental processes. Here we show that components of both bone morphogenetic protein/growth differentiation factor and TGF-beta/activin/Nodal branches of TGF-beta superfamily signaling are expressed in the developing subpallium. Furthermore, Smad proteins, transcriptional effectors of TGF-beta signaling, are co-expressed and physically interact in the basal ganglia with Dlx homeodomain transcription factors, which are critical regulators of the differentiation, migration and survival of telencephalic GABAergic neurons. We also show that Dlx and Smad proteins localize to promoters/enhancers of a number of common telencephalic genes in vivo and that Smad proteins co-activate transcription with Dlx family members, except with certain mutated human DLX proteins identified in autistic individuals. In agreement with these observations, expression of dominant-negative Smads in the developing basal ganglia phenocopies the cell migration defects observed in Dlx1/2-deficient mice. Together, these results suggest that TGF-beta superfamily signaling plays a role in telencephalic GABAergic neuron development through functional interactions with Dlx transcription factors. ELECTRONIC SUPPLEMENTARY MATERIAL: The online version of this article (doi:10.1007/s11689-009-9035-6) contains supplementary material, which is available to authorized users.