Project description:Primary human pancreatic ductal organoids (HPDO) have emerged as a model to study pancreas biology and model disease like pancreatitis and pancreatic cancer. Yet, donor material availability, genetic variability and a lack of extensive benchmarking to healthy and disease pancreas limits the range of applications. To address this gap, we established porcine pancreatic ductal organoids (PPDO) as a system from a reliable, genetically defined and easily obtainable source to model pancreatic ductal/progenitor biology. We benchmarked PPDO to HPDO and primary porcine pancreas using single-cell RNA sequencing (scRNA-Seq). We observed no overt phenotypic differences in PPDO derived from distinct developmental stages using extensive proteomics profiling, with a WNT/basal cell signaling enriched population characterizing PPDO. PPDO exhibited differentiation potential towards mature ductal cells and limited potential towards endocrine lineages. We used PPDO as a chemical screening platform to assess the safety of FDA-approved drugs and showed conserved toxicity of statins and α-adrenergic receptor inhibitors between PPDO and HPDO cultures. Overall, our results highlight the PPDO as a model for mammalian duct/progenitor applications.

Project description:Primary human pancreatic ductal organoids (HPDO) have emerged as a model to study pancreas biology and disease. Yet, donor material availability, and a lack of extensive benchmarking limits the range of applications. To address this gap, we established porcine pancreatic ductal organoids (PPDO) as a system from an easily obtainable source to model pancreatic ductal/progenitor biology. We benchmarked PPDO to HPDO and primary porcine pancreas using single-cell RNA sequencing (scRNA-Seq). We observed no overt phenotypic differences in PPDO derived from distinct developmental stages, with a WNT signaling enriched population characterizing PPDO. PPDO exhibited differentiation potential towards mature ductal cells and limited potential towards endocrine lineages. We used PPDO as a platform to assess the safety of FDA-approved drugs and showed conserved toxicity of statins and α-adrenergic receptor inhibitors between PPDO and HPDO cultures. Overall, our results highlight the PPDO as a model for mammalian duct/progenitor applications.

Project description:Primary human pancreatic ductal organoids (HPDO) have emerged as a model to study pancreas biology and disease. Yet, donor material availability, and a lack of extensive benchmarking limits the range of applications. To address this gap, we established porcine pancreatic ductal organoids (PPDO) as a system from an easily obtainable source to model pancreatic ductal/progenitor biology. We benchmarked PPDO to HPDO and primary porcine pancreas using single-cell RNA sequencing (scRNA-Seq). We observed no overt phenotypic differences in PPDO derived from distinct developmental stages, with a WNT signaling enriched population characterizing PPDO. PPDO exhibited differentiation potential towards mature ductal cells and limited potential towards endocrine lineages. We used PPDO as a platform to assess the safety of FDA-approved drugs and showed conserved toxicity of statins and α-adrenergic receptor inhibitors between PPDO and HPDO cultures. Overall, our results highlight the PPDO as a model for mammalian duct/progenitor applications.

Project description:Primary human pancreatic ductal organoids (HPDO) have emerged as a model to study pancreas biology and disease. Yet, donor material availability, and a lack of extensive benchmarking limits the range of applications. To address this gap, we established porcine pancreatic ductal organoids (PPDO) as a system from an easily obtainable source to model pancreatic ductal/progenitor biology. We benchmarked PPDO to HPDO and primary porcine pancreas using single-cell RNA sequencing (scRNA-Seq). We observed no overt phenotypic differences in PPDO derived from distinct developmental stages, with a WNT signaling enriched population characterizing PPDO. PPDO exhibited differentiation potential towards mature ductal cells and limited potential towards endocrine lineages. We used PPDO as a platform to assess the safety of FDA-approved drugs and showed conserved toxicity of statins and α-adrenergic receptor inhibitors between PPDO and HPDO cultures. Overall, our results highlight the PPDO as a model for mammalian duct/progenitor applications.

Project description:To investigate pancreatic, ductal CFTR function, organoids from porcine pancreas were cultured. RNA was extracted from pancreatic organoids at passage 3 and 5 after organoid establishment.

Project description:With a five-year survival rate of 9%, pancreatic ductal adenocarcinoma (PDAC) the deadliest of all cancers. The rapid mortality makes PDAC difficult to research, and inspires a resolve to create reliable, tractable cellular models for preclinical cancer research. PDAC organoids are increasing used to model PDAC as they maintain the differentiation status, molecular and genomic signatures of the original tumour. In this paper, we present novel methodologies and experimental approaches to develop PDAC organoids from PDX tumours, and the simultaneous development of matched primary cell lines. Moreover, we also identify a method of recapitulating primary cell line cultures to organoids (CLOs). We highlight the usefulness of CLOs as PDAC organoid models, as they maintain similar transcriptomic signatures as their matched patient-derived organoids and PDXs. These models provide a manageable, expandable in vitro resource for downstream applications such as high throughput screening, functional genomics, and tumour microenvironment studies.

Project description:Pancreatic duct organoids have emerged as a valuable tool for investigating pancreas biology and physiology through in vitro modeling. Despite their widespread use, a comprehensive understanding of the cellular heterogeneity of organoids and their underlying tissue remains elusive. Here we performed single-cell transcriptomic profiling of human adult pancreatic exocrine tissue and their derived organoids, revealing a gradient of keratin expression within the ductal network that clustered cells into two distinct low- and high-keratin subpopulations. Keratin-high cells display a higher capacity to form organoids while keratin-low cells express stemness associated markers. Finally, comparative gene expression analysis between ductal tissue and derived organoids revealed a partial recapitulation of the in vivo heterogeneity. These findings further our knowledge on pancreatic duct organoids and pave the way for future investigations into the heterogeneity of the pancreatic ductal syste

Project description:Full protein measurements from in vitro differentiation of the human embryonic stem cell line HUES8 into pancreatic progenitors (PP) and pancreatic duct-like organoids (PDLOs). Protein intensities were quantified by mass spectrometry analysis from PPs at day 13 and from PDLOs at day 59. Please see related publication “Modelling Plasticity and Dysplasia of Pancreatic Ductal Organoids Derived from Human Pluripotent Stem Cells” for experimental details.

Project description:Organoids are cultivated in extracellular matrix from different basement membrane extracts (BMEs) that are most commonly acquired commercially. However, the impact of different sources and lots of BMEs on organoid drug response is unknown. Here, we tested the impact of BME source and lot on proliferation, chemotherapy and targeted therapy drug response, and global gene expression in mouse and human pancreatic ductal adenocarcinoma organoids. Both mouse and human organoids displayed increased proliferation in Matrigel (Corning) compared to Cultrex (RnD) and UltiMatrix (RnD). However, we observed no substantial impact on drug response when organoids were cultured in Matrigel, Cultrex, or UltiMatrix. We also did not observe major shifts in gene expression across the different BME sources.

Project description:The aggressiveness of pancreatic ductal adenocarcinoma (PDAC) is affected by a tumor microenvironment (TME). In this study, to recapitulate PDAC TME ex vivo, we cocultured patient-derived PDAC cells with mesenchymal and vascular endothelial cells derived from human induced-pluripotent stem cells (hiPSCs) to create a fused pancreatic cancer organoid (FPCO) in air–liquid interface. FPCOs were further induced to resemble two distinct parts of a PDAC tissue. Owing to various types of cancer associated fibroblasts (CAFs) derived from hiPSCs, the TME consisted of abundant extracellular matrix proteins, which likely conferred strong drug resistance to PDAC cells in one type of FPCOs. Because of re-proliferation capacity of PDAC cells after anticancer drug treatment, the other FPCO is the first culture system for investigating PDAC recurrence. Introducing hiPSC technology, we have created, for the first time, the PDAC organoids representing the heterogeneity of PDAC tissue, a potential platform for screening anticancer drugs.