Genomic profiling of EOC organoids: low-coverage whole-genome sequencing
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ABSTRACT: Organoids were established from patients with ovarian cancer. DNA was extracted from organoids and primary tissue to investigate whether organoids retain the same genomic abnormalities and disease-associated features.
Project description:Organoids were established from patients with ovarian cancer. DNA was extracted from organoids and primary tissue to investigate whether organoids retain the same genomic abnormalities and disease-associated features.
Project description:Knowledge on tooth epithelial stem cells and corresponding biology in humans is sparse. Here, we developed an organoid model, typically replicating epithelial tissue stem cell biology, starting from human tooth. Dental follicle (DF), isolated from extracted wisdom teeth, efficiently generated long-term expandable epithelial organoids. The organoids displayed a tooth stemness phenotype as present in DF’s Epithelial Cell Rests of Malassez, a compartment deemed to contain tooth epithelial stem cells. To further decode the organoids in more granular detail, we applied scRNA-seq analysis on DF-derived organoids (passage 1 (P1) and P4) together with their primary tissue. Additionally, to decipher the amelogenesis-resembling process that takes place in the tooth organoids upon differentiation, we performed scRNA-seq analysis of P4 organoids switched to mineralization-inducing medium for 8 days.
Project description:Organoids from KPC pancreatic tumor tissue was treated with growth medium or conditional medium of mast cells treated with WT or BAG6 KO EVS of Pan02.
Project description:Low-coverage whole genome of endometrium cancer derived organoids. Organoids were established from patients with endometrial diseases and DNA was extracted from low passage number and high passage number and compared with the primary tissue when available to investigate whether organoids retain the same genomic abnormalities and disease-associated features.
Project description:This study aims to compare in vivo human trophoblast differentiation into EVTs to different in vitro trophoblast organoids using single-cell and single-nuclei RNA sequencing. The study includes two type of systems: human primary trophoblast organoids (PTO) and trophoblast stem cells (TSCs). Trophoblast stem cell (TSC) lines BTS5 and BTS11 derived by Okae and colleagues were grown as described previously (Okae et al. 2018) and together with EVT media. Primary trophoblast organoids (PTO) were grown and differentiated into EVT as previously described by Turco & Sheridan (Turco et al 2018; Sheridan et al 2020). This study shows that the main regulatory programs mediating EVT invasion in vivo are preserved in in vitro models of EVT differentiation from primary trophoblast organoids and trophoblast stem cells.
Project description:Organoid models provide powerful tools to study tissue biology and development in a dish. Here, we established first-time organoid models from early-postnatal (postnatal day 7) mouse molar and incisor, capable of differentiation toward ameloblast-like cells in vitro. To more in detail characterise organoids from mouse molar and incisor, bulk RNA-sequencing was performed on the following (1) early passage (passage 0) organoids from both tooth types grown in basal tooth organoid medium (TOM) with or without addition of exogenous epidermal growth factor (EGF); and (2) late passage (passage 5) organoids grown in TOM+EGF or differentiation medium (DM).
Project description:This project used snRNA-seq and Molecular Cartography (single cell spatial transcriptomics) to investigate the relation between morphology and molecular identity in human brain organoids.