Project description:Organoids are a valuable 3D model to study the differentiated functions of the human intestinal epithelium. They are a particularly powerful tool to measure epithelial transport processs in health and disease. Though biological assays such as organoid swelling and intraluminal pH measurements are well established, their underlying functional genomics are not well characterized. Here we combine genome-wide analysis of open chromatin by ATAC-seq with transcriptome mapping by RNA-seq to define the genomic signature of human intestinal organoids (HIOs). These data provide an important tool for investigating key physiological and biochemical processes in the intestinal epithelium. We next compared the transcriptome and open chromatin profiles of HIOs with equivalent datasets from the Caco2 colorectal carcinoma line, which is an important 2D model of the intestinal epithelium. Our results define common features of the intestinal epithelium in HIO and Caco2 and further illustrate the cancer-associated program of the cell line. Generation of Caco2 organoids enabled interrogation of the molecular divergence of the 2D and 3D cultures. Over-represented motif analysis of open chromatin peaks identified Caudal Type Homeobox 2 (CDX2) as a key activating transcription factor in HIO, but not in monolayer cultures of Caco2. However, the CDX2 motif becomes overrepresented in open chromatin from Caco2 organoids, reinforcing the importance of this factor in intestinal epithelial differentiation and function. Intersection of the HIO and Caco2 transcriptomes further showed functional overlap in pathways of ion transport and tight junction integrity among others. These data make an important contribution to understanding human intestinal organoid biology.

Project description:Organoids are a valuable 3D model to study the differentiated functions of the human intestinal epithelium. They are a particularly powerful tool to measure epithelial transport processs in health and disease. Though biological assays such as organoid swelling and intraluminal pH measurements are well established, their underlying functional genomics are not well characterized. Here we combine genome-wide analysis of open chromatin by ATAC-seq with transcriptome mapping by RNA-seq to define the genomic signature of human intestinal organoids (HIOs). These data provide an important tool for investigating key physiological and biochemical processes in the intestinal epithelium. We next compared the transcriptome and open chromatin profiles of HIOs with equivalent datasets from the Caco2 colorectal carcinoma line, which is an important 2D model of the intestinal epithelium. Our results define common features of the intestinal epithelium in HIO and Caco2 and further illustrate the cancer-associated program of the cell line. Generation of Caco2 organoids enabled interrogation of the molecular divergence of the 2D and 3D cultures. Over-represented motif analysis of open chromatin peaks identified Caudal Type Homeobox 2 (CDX2) as a key activating transcription factor in HIO, but not in monolayer cultures of Caco2. However, the CDX2 motif becomes overrepresented in open chromatin from Caco2 organoids, reinforcing the importance of this factor in intestinal epithelial differentiation and function. Intersection of the HIO and Caco2 transcriptomes further showed functional overlap in pathways of ion transport and tight junction integrity among others. These data make an important contribution to understanding human intestinal organoid biology.

Project description:The development of human pluripotent stem cell (hPSC)- derived small intestinal organoids (HIOs) has led to an improved understanding of human intestinal development and physiology. HIOs generated using directed differentiation lack some cellular populations found in the native organ, including vasculature. We performed single cell RNA sequencing (scRNA-seq) on approximately 13,000 cells at various timepoints (0, 3, 7, and 14 days) across HIO in vitro development and observed a transient population of endothelial-like cells (ECs) present within HIOs early during differentiation. Our data demonstrate that EC-like cells fail to be robustly maintained in long term culture. Here, we have developed a new directed differentiation approach to enhance co-differentiation and maintenance of ECs within HIOs, leading to the development of vascularized HIOs (vHIOs). scRNAseq was used to compare vHIOs to control HIOs after 59d months in culture.

Project description:Human Intestinal Organoids (HIOs) generated from embryonic and/or induced pluripotent stem cell lines offer an avenue to study both developmental and human specific disease states. Recently, progress has been made in scaling and maturing these inherently immature tissues through transplanting them in vivo. However, these resultant grafts best approximate fetal intestinal tissue thus limiting their utility. To induce growth and maturation of HIOs we used a nitinol spring device to mechanically induce enterogenesis of HIO in vivo. HIOs are cultured prior to implantation within the mesentery of immunodeficient mice. They are allowed to grow, vascularize, and mature before a second procedure is performed wherein a compressed nitinol spring is implanted within the lumen of the transplanted HIO (tHIO). Next Generation RNA sequencing was performed across transplanted samples as well as on human surgical samples to highlight the transcriptional similarities and differences between groups. Transcriptionally, the tHIO+S samples were more similar to human tissues than the tHIO. With these initial experiments, we concluded that the application of an intraluminal uniaxial force is a practical method to induce maturation of tHIOs in vivo without concomitant architectural disruptions. While our current system does lack certain complexities, we have demonstrated enterogenesis by means of mechanical manipulation.

Project description:Human gastrointestinal (GI) organoids derived from pluripotent stem cells have unique potential for studying organogenesis, physiology, and diseases. To this end, their transplantation into animal models to further their development into functional organs provides a valuable tool. However, organoids from different GI regions, for example, the esophagus or intestine, harbor different engraftment capabilities. Here, we developed a tissue-engineering approach and show that enhancing the mesenchyme-to-endoderm ratio enables reliable engraftment of GI organoids. However, endoderm/mesoderm recombinations reveal that only Human Intestinal Organoid (HIO) mesenchyme allows full development of GI epitheliums in vivo. Comparative mesenchyme analysis from esophageal, gastric, intestinal, and colonic organoids shows endothelial cell enrichment within the HIO mesenchyme, and we demonstrate by endothelial cell depletion or addition that these cells are required and sufficient for proper GI organoid development in vivo. Our findings highlight the optimal mesenchymal cellular composition needed to support GI organoid engraftment, tissue growth, and function.

Project description:Background: We previously reported Crohn’s Disease (CD) ileal macrophage and fibroblast gene expression modules linked to future strictures, and identified small molecules which may reverse this gene signature. Here we developed a model system to test a lead candidate, eicosatetraynoic acid (ETYA), a Peroxisome Proliferator-Activated Receptor (PPAR) agonist. Methods: CD patient induced pluripotent stem cells (iPSC) were differentiated into macrophages and human intestinal organoids (HIOs). Macrophages and macrophage:HIO co-cultures were exposed to lipopolysaccharide (LPS) with and without ETYA pre-treatment. Cytospin and flow cytometry characterized macrophage morphology and activation markers, and RNA sequencing defined the global pattern of macrophage gene expression. TaqMan Low Density Array, Luminex multiplex assay, immunohistologic staining, and sirius red polarized light microscopy were performed to measure macrophage cytokine production and HIO pro-fibrotic gene expression and collagen content. Results: iPSC-derived macrophages exhibited morphology similar to primary macrophages and expressed inflammatory macrophage cell surface markers including CD64 and CD68. LPS-stimulated macrophages expressed a global pattern of gene expression enriched in CD ileal inflammatory macrophages and matrisome secreted products, and produced cytokines and chemokines including CCL2, IL1B, and OSM implicated in refractory disease. ETYA suppressed CD64 abundance and pro-fibrotic gene expression pathways in LPS stimulated macrophages. Co-culture of LPS-primed macrophages with HIO led to up-regulation fibroblast activation genes including ACTA2 and COL1A1, and an increase in HIO collagen content. ETYA pre-treatment prevented pro-fibrotic effects of LPS-primed macrophages. Conclusions: ETYA inhibits pro-fibrotic effects of LPS-primed macrophages upon co-cultured HIO. This model system may be used to screen personalized effects of candidate small molecules upon inflammatory and fibrotic pathways implicated in refractory CD patients.

Project description:Background: We previously reported Crohn’s Disease (CD) ileal macrophage and fibroblast gene expression modules linked to future strictures, and identified small molecules which may reverse this gene signature. Here we developed a model system to test a lead candidate, eicosatetraynoic acid (ETYA), a Peroxisome Proliferator-Activated Receptor (PPAR) agonist. Methods: CD patient induced pluripotent stem cells (iPSC) were differentiated into macrophages and human intestinal organoids (HIOs). Macrophages and macrophage:HIO co-cultures were exposed to lipopolysaccharide (LPS) with and without ETYA pre-treatment. Cytospin and flow cytometry characterized macrophage morphology and activation markers, and RNA sequencing defined the global pattern of macrophage gene expression. TaqMan Low Density Array, Luminex multiplex assay, immunohistologic staining, and sirius red polarized light microscopy were performed to measure macrophage cytokine production and HIO pro-fibrotic gene expression and collagen content. Results: iPSC-derived macrophages exhibited morphology similar to primary macrophages and expressed inflammatory macrophage cell surface markers including CD64 and CD68. LPS-stimulated macrophages expressed a global pattern of gene expression enriched in CD ileal inflammatory macrophages and matrisome secreted products, and produced cytokines and chemokines including CCL2, IL1B, and OSM implicated in refractory disease. ETYA suppressed CD64 abundance and pro-fibrotic gene expression pathways in LPS stimulated macrophages. Co-culture of LPS-primed macrophages with HIO led to up-regulation fibroblast activation genes including ACTA2 and COL1A1, and an increase in HIO collagen content. ETYA pre-treatment prevented pro-fibrotic effects of LPS-primed macrophages. Conclusions: ETYA inhibits pro-fibrotic effects of LPS-primed macrophages upon co-cultured HIO. This model system may be used to screen personalized effects of candidate small molecules upon inflammatory and fibrotic pathways implicated in refractory CD patients.

Project description:Cronkhite Canada Syndrome (CCS) is a rare, non-inherited polyposis syndrome affecting 1 in a million individuals. Despite over 50 years of CCS cases, the etiopathogenesis and optimal treatment for CCS remains unknown due to the rarity of the disease and lack of model systems. To investigate and better understand the etiology of CCS, we generated human intestinal organoids (HIOs) from intestinal stem cells isolated from two CCS patients. We discovered that CCS HIOs have unique growth characteristics and have increased serotonin (5-hydroxytryptamine, 5HT) positive cells. Further investigation revealed that 5HT can induce HIO proliferation, and inhibition of 5HT results in decreased proliferation in the CCS HIOs. Our findings indicate that dysregulation of 5HT may explain polyposis observed in CCS and provide new insight into regulation of the intestinal stem cell. This work illustrates the important contribution organoids can make to understanding disease etiology and identifying novel therapies.

Project description:In vitro human pluripotent stem cell derived intestinal organoids (HIOs) are immature and lack for diverse differentiated secretory cell types. We would like to test the hypothesis whether addition of a mesenchyme secreting ligand which is depleted in canonical organoid culture media could increase the maturity and secretory cell type diversity in HIOs in vitro. To do this, we adapted the directed differentiation protocol of HIOs by growing HIOs in media with EGF, NOGGIN, R-spondin-1 (ENR) for 30 days, isolated epithelial cells with dispase, recovered them with adult intestinal enteroid media with Wnt-3A (WENR). Then we introduced the mesenchyme secreting ligand NRG1 to the established enteroid culture (WENR+NRG1) and compared them to the enteroids grown in control condition (WENR).

Project description:Deriving human intestinal organoids with functional tissue-resident macrophages all from pluripotent stem cells