Project description:Sliced Human Cortical Organoids for Modeling Distinct Cortical Neuronal Layer Formation

Project description:Here we used human cortical brain organoids to probe the longitudinal impact of GSK3 inhibition through multiple developmental stages. Chronic GSK3 inhibition increased the proliferation of neural progenitors and caused massive derangement of cortical tissue architecture. Cortical organoids were differentiated as previously described (Paşca et al., 2015, doi: 10.1038/nmeth.3415.).Chronic GSK3 inhibition was performed by adding CHIR99021 (Merck SML1046) to the medium at day 0 (1 microM) and kept throughout the differentiation process until reaching the respective collection timepoints (day 18, day 50, day 100).

Project description:Here we used human cortical brain organoids to probe the longitudinal impact of GSK3 inhibition through multiple developmental stages. Chronic GSK3 inhibition increased the proliferation of neural progenitors and caused massive derangement of cortical tissue architecture. Cortical organoids were differentiated as previously described (Paşca et al., 2015, doi: 10.1038/nmeth.3415.). Chronic GSK3 inhibition was performed by adding CHIR99021 (Merck SML1046) to the medium at day 0 (1 microM) and kept throughout the differentiation process until reaching the respective collection timepoints (day 50, day 100).

Project description:Human neural organoid models have become an important tool for studying neurobiology. In this work, we compared Matrigel to an N-cadherin peptide-functionalized gelatin methacryloyl hydrogel (termed GelMA-Cad) for culturing cortical neural organoids. Specifically, we compare five materials: (1) Matrigel, (2) GelMA-Cad with high crosslinker (HC), (3) GelMA-Cad with low crosslinker (LC), (4) GelMA HC and (5) GelMA LC. We determined that both mechanical properties and peptide presentation can tune cell fate and diversity in gelatin-based matrices during differentiation. Of particular note, cortical organoids cultured in GelMA-Cad produce higher numbers of neurogenic and ciliated radial glia and upper-layer excitatory neurons—an important population for modeling neurodegenerative disease—compared to GelMA and Matrigel controls.

Project description:Cerebral organoids – three-dimensional cultures of human cerebral tissue derived from pluripotent stem cells – have emerged as models of human cortical development. However, the extent to which in vitro organoid systems recapitulate neural progenitor cell proliferation and neuronal differentiation programs observed in vivo remains unclear. Here we use single-cell RNA sequencing (scRNA-seq) to dissect and compare cell composition and progenitor-to-neuron lineage relationships in human cerebral organoids and fetal neocortex. Covariation network analysis using the fetal neocortex data reveals known and novel interactions among genes central to neural progenitor proliferation and neuronal differentiation. In the organoid, we detect diverse progenitors and differentiated cell types of neuronal and mesenchymal lineages, and identify cells that derived from regions resembling the fetal neocortex. We find that these organoid cortical cells use gene expression programs remarkably similar to those of the fetal tissue in order to organize into cerebral cortex-like regions. Our comparison of in vivo and in vitro cortical single cell transcriptomes illuminates the genetic features underlying human cortical development that can be studied in organoid cultures. 734 single-cell transcriptomes from human fetal neocortex or human cerebral organoids from multiple time points were analyzed in this study. All single cell samples were processed on the microfluidic Fluidigm C1 platform and contain 92 external RNA spike-ins. Fetal neocortex data were generated at 12 weeks post conception (chip 1: 81 cells; chip 2: 83 cells) and 13 weeks post conception (62 cells). Cerebral organoid data were generated from dissociated whole organoids derived from induced pluripotent stem cell line 409B2 (iPSC 409B2) at 33 days (40 cells), 35 days (68 cells), 37 days (71 cells), 41 days (74 cells), and 65 days (80 cells) after the start of embryoid body culture. Cerebral organoid data were also generated from microdissected cortical-like regions from H9 embryonic stem cell derived organoids at 53 days (region 1, 48 cells; region 2, 48 cells) or from iPSC 409B2 organoids at 58 days (region 3, 43 cells; region 4, 36 cells).

Project description:As cortical organoids consist of a heterogeneous population of cell-types, 6-month-old DM1 and Rett syndrome cortical organoids were subjected to single cell RNA-seq (scRNA-seq) analysis to determine which cell type(s) CELF2’s RNA targets are expressed in. Unsupervised clustering was implemented on the combined dataset of 8595 cells from control, DM600, and DM1200 cortical organoids that consisted of ~2865 cells per organoid line and ~17,575 reads per cell to identify genotype-specific clusters at 6-months post-differentiation. Uniform Manifold Approximation and Projection (UMAP) for dimension reduction revealed clear differences between control and DM1 organoids. From the expression of established cell-type specific gene markers, smaller sub-clusters were combined to represent four major cell classes: neural progenitors, intermediate neural progenitors, glutamatergic cortical neurons, and glial cells.

Project description:Current organoid protocols are widely used to mechanistically study cortical development, evolution and brain pathologies. While these systems generate all major cortical cell types in histologically distinct compartments, they lack cortical area topography, which is initiated by gradients of signaling molecules released by signaling organizers that establish transcriptionally distinct domains along the rostro-caudal axis of the developing cortex. Here, we engineer human cortical assembloids that combine an organizer-like structure expressing FGF8 with an elongated organoid design to enable the controlled modulation of FGF8 signaling along the longitudinal organoid axis. We demonstrate that individual polarized cortical assembloids (polCA) mount a position-dependent transcriptional program that matches the in vivo rostro-caudal gene expression patterns. Importantly, positional identity is lost in polCA carrying a mutation in the FGFR3 gene associated with temporal lobe malformations and intellectual disability in humans. Similar to in vivo, this program is accompanied by transcriptional divergence of radial glia cells and excitatory neurons and their segregation along the longitudinal axis of individual organoids. Thus, this method reproduces in vivo cortical topography in individual organoids and enables the analysis of area-related phenotypes underlying human disorders.

Project description:Current organoid protocols are widely used to mechanistically study cortical development, evolution and brain pathologies. While these systems generate all major cortical cell types in histologically distinct compartments, they lack cortical area topography, which is initiated by gradients of signaling molecules released by signaling organizers that establish transcriptionally distinct domains along the rostro-caudal axis of the developing cortex. Here, we engineer human cortical assembloids that combine an organizer-like structure expressing FGF8 with an elongated organoid design to enable the controlled modulation of FGF8 signaling along the longitudinal organoid axis. We demonstrate that individual polarized cortical assembloids (polCA) mount a position-dependent transcriptional program that matches the in vivo rostro-caudal gene expression patterns. Importantly, positional identity is lost in polCA carrying a mutation in the FGFR3 gene associated with temporal lobe malformations and intellectual disability in humans. Similar to in vivo, this program is accompanied by transcriptional divergence of radial glia cells and excitatory neurons and their segregation along the longitudinal axis of individual organoids. Thus, this method reproduces in vivo cortical topography in individual organoids and enables the analysis of area-related phenotypes underlying human disorders.

Project description:Modeling Focal Cortical Dysplasia (FCD) using cortical organoids

Project description:Cerebral organoids exhibit broad regional heterogeneity accompanied by limited cortical cellular diversity under a variety of derivation methods, suggesting inadequate patterning of early neural stem cell (NSC) starting populations. Here we show that a short combined Dual SMAD/WNT inhibition course during early organoid establishment is sufficient for yielding robust and lasting cortical identity with efficient suppression of non-cortical fates in organoid NSCs. In contrast, other widely used methods are inconsistent in their cortical specification capacity. Furthermore, combined inhibition selectively enriches for outer radial glia (oRG) cells in organoids that demarcate well-defined outer sub-ventricular (oSVZ)-like regions. Finally, combined inhibition enables superior NSC radial organization, further facilitates the generation of molecularly distinct deep and upper cortical layer neurons, and uncovers cortex-specific microcephaly defects. Thus, combined inhibition is critical for establishing a rich cortical cell repertoire, for enabling fundamental cytoarchitectural features of cortical development, and for meaningful disease modeling.