Project description:We developed a method of generating human induced pluripotent stem cell (iPSC)-derived mesenchymal cells (iMES) that were able to induce AT1 and AT2 epithelial lineage cells in organoids. Transcriptomic analysis of human fetal lung fibroblasts (HFLF), human dermal fibroblasts (HDF), and their corresponding iMES revealed that iMES harbor characteristics of lung distal tip mesenchyme.

Project description:We have developed a method to generate human induced pluripotent stem cell (iPSC)-derived mesenchymal cells (iMES) that were able to induce AT1 and AT2 epithelial cells within their organoids (iMES-AO). Single-cell transcriptome analysis comparing iMES-AO with our previously reported alveolar organoids using human fetal lung fibroblasts delineated not only differences in composition of epithelial lineages but also distinctive mesenchymal lineages.

Project description:Compare the gene expression profiles of parental (1383D2) or iHER2-iPSC derived lung organoids

Project description:Background & Aims Patient-derived gastrointestinal organoids are powerful tools for studying human physiology and disease. However, generating organoids requires prompt isolation and culture of fresh tissue, which is labor and time intensive, placing restraints on basic and clinical research. For example organoid biobanking efforts, or the ability to obtain specimens from distant locations that lack the expertise to culture organoids, is limited by current approaches. We sought to develop a method by which tissue biopsies from patients could be cryo-preserved, stored, or shipped, and later thawed in order to establish live organoid cultures. Methods A method for freezing and recovery, along with straightforward isolation methods using readily available materials were developed. Epithelial isolation and culture conditions were optimized to promote cell survival and the establishment of long-term culture post-thawing. Results Patient biopsies from stomach, duodenum, ileum, colon and from adenomateous colonic polyps were frozen, subsequently thawed and used to successfully establish patient-specific epithelium-only organoid cultures with 100% efficiency (n=31 independent patient biopsies from different regions of the GI tract). Frozen tissue could be shipped internationally and across the United States and used to establish successful organoid cultures. Organoid cultures could be expanded, passaged and frozen down for long-term storage. RNA-sequencing demonstrates that organoids derived from fresh tissue or from frozen biopsies are >99% transcriptionally identical. Conclusions Cryo-preservation of human tissue biopsies followed by the establishment of long-term, expandable cultures has negligible effect on transcription when compared to freshly prepared organoids, and will be of immense benefit to research and for clinical applications. This technique will allow for the establishment of biobanks of human tissues that can be revived and cultured in the future as well as transported across the globe for research, therapeutic or diagnostic use in remote labs and/or clinics.

Project description:Conventional reprogramming methods rely on the ectopic expression of transcription factors to reprogram somatic cells into induced pluripotent stem cells (iPSC). Forced expression of transcription factors might lead to off-target gene activation and heterogeneous reprogramming, resulting in the emergence of alternative cell types and aberrant iPSC. Activation of endogenous pluripotency factors by CRISPR activation (CRISPRa) can potentially reduce this heterogeneity. Here we describe a high efficiency reprogramming of human somatic cells into iPSC using optimized CRISPRa. Efficient reprogramming was dependent on the additional targeting of the embryo genome activation-enriched Alu-motif and the miR-302/367 locus. Single-cell transcriptome analysis revealed that the optimized CRISPRa reprogrammed cells with more directly and specifically into the pluripotent state when compared to the conventional reprogramming method. These findings support the use of CRISPRa for high quality reprogramming of human iPSC.

Project description:Conventional reprogramming methods rely on the ectopic expression of transcription factors to reprogram somatic cells into induced pluripotent stem cells (iPSC). Forced expression of transcription factors might lead to off-target gene activation and heterogeneous reprogramming, resulting in the emergence of alternative cell types and aberrant iPSC. Activation of endogenous pluripotency factors by CRISPR activation (CRISPRa) can potentially reduce this heterogeneity. Here we describe a high efficiency reprogramming of human somatic cells into iPSC using optimized CRISPRa. Efficient reprogramming was dependent on the additional targeting of the embryo genome activation-enriched Alu-motif and the miR-302/367 locus. Single-cell transcriptome analysis revealed that the optimized CRISPRa reprogrammed cells with more directly and specifically into the pluripotent state when compared to the conventional reprogramming method. These findings support the use of CRISPRa for high quality reprogramming of human iPSC.

Project description:We have optimized CRISPR/Cas genome editing in human Embryonic Stem Cells (hESCs) and developed a method to generate hESC-derived eye organoids to investigate the cell type composition of these eye organoids using single cell RNA sequencing. We also investigate the consequences of the loss of a new AMD-associated gene, DRAM2, on the cell composition of the eye organoids.

Project description:Conventional reprogramming methods rely on the ectopic expression of transcription factors to reprogram somatic cells into induced pluripotent stem cells (iPSC). Forced expression of transcription factors might lead to off-target gene activation and heterogeneous reprogramming, resulting in the emergence of alternative cell types and aberrant iPSC. Activation of endogenous pluripotency factors by CRISPR activation (CRISPRa) can potentially reduce this heterogeneity. Here we describe a high efficiency reprogramming of human somatic cells into iPSC using optimized CRISPRa. Efficient reprogramming was dependent on the additional targeting of the embryo genome activation-enriched Alu-motif and the miR-302/367 locus. Single-cell transcriptome analysis revealed that the optimized CRISPRa reprogrammed cells with more directly and specifically into the pluripotent state when compared to the conventional reprogramming method. These findings support the use of CRISPRa for high quality reprogramming of human iPSC. This SuperSeries is composed of the SubSeries listed below.

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:iPSC-derived microglia export cholesterol to neuronal cells in human brain organoids and promote their maturation