Project description:Human lung organoids (HLOs) were derived from human embryonic stem cell line H9 NIH registry #0062. Sequencing of HLOs was performed by the UM DNA Sequencing Core, using Illumina Hi-Seq platform and single-end 50 bp reads. The UM Bioinformatics Core downloaded the reads files from the Sequencing Core storage, and concatenated those into a single .fastq file for each sample. 3 HLOs were cultured for 65 days and 3 HLOs were cultured in vitro for 110 days. HLO Culture Protocol 4-day Activin A (R&D systems) differentiation protocol was used to derive definitive endoderm from human pluripotent stem cells (hPSCs). Cells were treated with Activin A (100ngml-1) for three consecutive days in RPMI 1640 media (Life Technologies) with increasing concentrations of 0%, 0.2% and 2% HyClone defined fetal bovine serum (dFBS, Thermo Scientific). The fourth day was a repeat of day 3 media (2% HyClone FBS). After differentiation into definitive endoderm, cells were incubated in foregut media (advanced DMEM/F12 plus N-2 and B27 supplement, 10mM Hepes, 1x L-Glutamine (200mM), 1x Penicillin-streptomycin (5,000 U/mL, all from Life Technologies)) with 200ng/mL Noggin (NOG, R&D Systems) and 10uM SB431542 (SB, Stemgent) for 4 days, SB, 500ng/mL FGF4 (R&D Systems), and 2 uM CHIR99021 (Chiron, Stemgent), and 1uM SAG (Enzo Life Sciences) for 4-6 days. After 4 days with treatment of growth factors, three-dimensional floating spheroids were present in the culture. Three-dimensional spheroids were transferred into Matrigel to support 3D growth. Spheroids were embedded in a droplet of Matrigel (BD Bioscience #356237) in one well of a 24 well plate, and incubated at room temperature for 10 minutes. After the Matrigel solidified, foregut media with 1% Fetal bovine serum (FBS, CAT#: 16000-044, Life Technologies) and 500ng/mL FGF10 (R&D Systems) were overlaid and replaced every 4 days. Organoids were transferred into new Matrigel droplets every 10 to 15 days.

Project description:Human intestinal organoids were grown in a typical 3D matrigel culture environment, or in an alginate gel, then a subset from each condition were xenotransplanted to vascularized and mature in vivo. Epithelium was isolated and epithelial only organoids (enteroids) were then grown from each condition prior to sequencing bulk RNA-sequencing.

Project description:Co-cultures of lung epithelium and mesenchyme are useful tools to study epithelial-mesenchymal crosstalk in lung development and disease. However, many previous attempts to generate such co-cultures have yielded poor juxtaposition between the epithelial and the mesenchymal lineage. In addition, induced pluripotent stem cell (iPSC)-derived co-cultures often contain generic mesenchyme that is not necessarily lung-specific. We sought to establish co-cultures of purified mouse iPSC-derived lung-specific mesenchyme and iPSC-derived lung epithelial progenitors. We used a mouse iPSC line carrying a lung mesenchyme-specific reporter/tracer (Tbx4-LERGFP) to generate lung mesenchymal progenitors by directed differentiation via a lateral plate mesodermal progenitor state (induced lung mesenchyme, iLM). In parallel we differentiated a mouse embryonic stem (ES) cell line carrying a Nkx2-1mCherry reporter into lung epithelial progenitor cells using our established directed differentiation protocol. We then combined the purified lung epithelial and mesenchymal progenitor cells and co-cultured them in distal or proximal differentiation media for 1 week on Matrigel. We find that cells self-organize into complex 3-dimensional organoids with closely juxtaposed epithelial and mesenchymal cells. Furthermore, co-culture affects the molecular phenotype of both lineages. Our iPSC-derived co-culture model can provide an inexhaustible source of cells for studying lung development, modeling diseases, and developing therapeutics.

Project description:This experiment compares the transcriptome profile of human spinal cord organoids generated from iPSCs in Matrigel, 1% alginate hydrogel, or 2% alginate hydrogel. Spinal cord organoids were generated from human iPSCs and then encapsulated in the respective hydrogels before further maturation. Organoids were harvested on days 30, 60, and 90 for each group. In addition to the differences between hydrogel groups, neuronal and glial markers at each time point were also assessed for the development of the organoids.

Project description:Epithelium-only cultured stem cells isolated from human pluripotent stem cell derived intestinal organoids grown in matrigel and alginate

Project description:Epithelium-only cultured stem cells isolated from human pluripotent stem cell derived intestinal organoids grown in matrigel and alginate

Project description:While biochemical regulation has been extensively studied in cerebral organoid modeling protocols, the role of mechano-regulation in directing stem cell fate and organoid development has been relatively unexplored. Volumetric compression, a key aspect of natural brain development, is known to influence neuronal differentiation. However, stiff interpenetrating network compression fails to accurately replicate the dynamic organoid development observed in nature. In this study, we present a novel method of heterogeneous embedding using an alginate-shell-Matrigel-core system. This approach allows for cell-Matrigel remodeling by the inner layer and provides moderate normal compression through the soft alginate outer layer. Our results show significant improvements in cell proliferation and maturation of cerebral organoids, as evidenced by increased expression of neuronal markers such as neurofilament (NF) and microtubule-associated protein 2 (MAP2). Compared to non-alginate embedding and alginate compression groups, volume growth remains unimpeded. Our findings demonstrate the successful mechanical regulation of cerebral organoids, which not only mimics the mechanical environment of brain development but also exhibits a regular growth profile with enhanced maturation. These results highlight the importance and potential practical applications of mechano-regulation in the establishment of brain organoids.

Project description:Idiopathic Pulmonary Fibrosis (IPF) is a devastating and life-threatening lung disease characterized by epithelial reprogramming and increased extracellular matrix deposition leading to loss of lung function. A prominent histopathological structure in the IPF lung are aberrant bronchioles filled with mucus, referred to as honeycomb cysts. These heterogeneous bronchiolized areas feature clusters of simple epithelium with Keratin (KRT)5+ basal-like cells interspersed with pseudostratified epithelium containing differentiated, hyperplastic epithelial cells as well as aberrant ciliated cells. Recent single-cell RNA sequencing studies of the lung epithelium shed further light into cellular subtypes unique to IPF, including basaloid KRT5-/KRT17+ cells present in the distal lung. However, IPF distal bronchiole cell subtypes still remain poorly characterized and their disease contribution remains underinvestigated. Using single-cell RNA sequencing of enriched EpCAM+ lung cells of the distal IPF lung, we identified G-protein coupled receptor (GPR) 87, as a marker of distal bronchioles and KRT5+ IPF basal cells contributing to impaired airway differentiation and honeycombing.

Project description:Here, we used single cell RNA-sequencing (scRNA-seq) to profile pluripotent stem cell derived human intestinal organoids (HIOs) grown in matrigel or a non-adhesive alginate hydrogel after 28 days of in vitro growth. Additionally, we used scRNA-seq to profile HIOs derived in the presence of Neuregulin 1 (NRG1) and/or EGF after 40 days of in vitro growth.

Project description:Here, we used single cell RNA-sequencing (scRNA-seq) to profile pluripotent stem cell derived human definitive endoderm and intestinal organoids (HIOs) at several timepoints of in vitro growth (7, 14, and 28 days) and after in vivo growth beneath the kidney capsule of a murine host (4 and 8 wks post-transplant). Additionally, we profiled HIOs grown in a non-adhesive alginate hydrogel and also CDX2 knockout HIOs. In order to benchmark the organoid cultures, we used scRNA-seq to profile primary human fetal esophagus (14.3 pcw, 16.7 pcw), stomach (6.7, 14.3, and 16.7 pcw), liver (14.4 pcw), small intestine ( 11.4 and 14.4 pcw) and colon (11.4, 14.4, and 18.9 pcw). Diverse cell lineages were captured across all tissues profiled, including: epithelium, mesenchyme, neurons, endothelium, and immune lineages.