Project description:We performed single-cell RNA sequencing of dorsal forebrain organoids at day 53 of differentiation upon treatment with Hyper-IL-6. The study aimed at investigation of the effects of Hyper-IL-6 on transcriptional profiles of dorsal forebrain organoids at single-cell level.

Project description:Description: RNA-seq of total RNA isolated from dorsal forebrain organoids at days 50 and 55 of differentiation. The study aimed at investigating the effects of 5 or 10 days of Hyper-IL-6 exposure on transcriptional profiles of dorsal forebrain organoids.

Project description:Cortical organoids generated from mESC from a Down Syndrome (DS) mouse model (Ts65Dn) were dissociated for single cell sequencing to understand whether differential gene expression in DS brains affects cell diversity and how the molecular events that control the development of these diverse types of neocortical neurons are affected by the trisomy. These results were generated in parallel to a single cell experiment in forebrain fetal tissue from WT and Ts65Dn mice.

Project description:To characterize cerebral organoids generated using STEMdiff Dorsal Forebrain Organoid Differentiation Kit were flash frozen on Day 30, we performed single cell RNA sequencing

Project description:Systematic analysis of the cellular and transcriptional landscape of brain organoids grown from multiple cell lines using four different protocols recapitulating dorsal and ventral forebrain, midbrain, and striatum via single-cell RNA sequencing.

Project description:Human pluripotent stem cell-derived 3D neural organoids have been shown to recapitulate the major features and cytoarchitecture of early human brain development. We used three commercially available kits: STEMdiff™ Cerebral Organoid Kit, STEMdiff™ Dorsal Forebrain Organoid Differentiation Kit, and STEMdiff™ Ventral Forebrain Organoid Differentiation Kit. These neural organoids contain unique and diverse cell types which model the early brain and are patterned with developmental cues. Here, we sought to investigate the cellular diversity of these organoids using single-cell RNA sequencing.

Project description:Temporal dynamics of prenatal brain development are influenced by changes in the microenvironment. Particularly, extracellular proteins contribute to the dynamic niche that balances neural stem cell proliferation and differentiation. Here, we present a resource for proteome and secretome analysis of human induced pluripotent stem cell-derived dorsal forebrain organoids over the early developmental period. We used liquid chromatography-mass spectrometry to identify proteins found in whole organoid and secreted proteins at days 20, 35, and 50 of dorsal forebrain organoid differentiation. We show that the whole organoid proteome demonstrates progression in the neurodevelopmental trajectory with reduced proliferation and increased neural differentiation over time. However, secretome analysis revealed a unique signature for developmental progression. Cell adhesion molecules are enriched in the secretome of day 35 organoids, while secretome of day 50 organoids is enriched with extracellular matrix proteins, demonstrating a change in the extracellular interactions over time of organoid differentiation and maturation. We, therefore, show the relevance of secretome analysis for the thorough study of extracellular matrix-related proteins and the importance of time course study of neural organoids to understand the subtle changes that guide human neurodevelopment.

Project description:Systematic analysis of the cellular and transcriptional landscape of brain organoids grown from multiple cell lines using four different protocols recapitulating dorsal and ventral forebrain, midbrain, and striatum via time-course bulk-RNA sequencing.

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:Cerebral organoids, three-dimensional cultures that model organogenesis, provide a new platform to investigate human brain development. High cost, variability and tissue heterogeneity limit accessibility and broad applications of current organoid technologies. Here we developed a miniaturized spinning bioreactor (SpinΩ) to generate forebrain-specific organoids from human iPSCs. These organoids recapitulate key features of human cortical development, including progenitor zone organization, neurogenesis, gene expression, and importantly, a distinct human-specific outer radial glia cell layer. We have also developed protocols to generate midbrain and hypothalamic organoids. Finally, we employed this forebrain organoid platform to model Zika virus (ZIKV) exposure. Quantitative analyses revealed that preferential, productive ZIKA infection of cortical neural progenitors leads to increased cell death and reduced proliferation, resulting in decreased neuronal cell layer volume that resembles microcephaly. Together, our brain region-specific organoids and SpinΩ provide an accessible and versatile platform for modeling human brain development and diseases, and for compound testing.