Project description:The goal of this study was to evaluate the transcriptional response of 4 human duodenal enteroid lines on monolayers to norovirus infections (GII.4). Enteroids were plated as monolayers in Intesticult (Stem Cell Technologies) proliferation medium. After 1 day of cell growth as a monolayer, the proliferation medium was changed with differentiation medium for 5 days. Five-day-differentiated monolayers were washed and were either mock-infected or inoculated with human norovirus supplemented with 500 μM glycochenodeoxycholic acid (GCDCA), for 1 to 2 h at 37°C. Total RNA was extracted using the Qiagen RNeasy kit and paired-end Illumina sequencing was performed.

Project description:Human Enteroid Monolayers: A Novel, Functionally-Stable Model for Investigating Oral Drug Disposition

Project description:Transcriptional response of human duodenal enteroid monolayers to norovirus infection

Project description:We report a robust, scalable method to generate iPSC-RPE using doxycycline-inducible expression of eye field transcription factors OTX2, PAX6 and MITF paired with RPE-permissive culture media. Doxycycline addition induces exogenous expression of these transcription factors in patient- and wildtype iPSCs to efficiently produce monolayers of RPE with characteristic morphology and gene expression. Further, these RPE monolayers display functionality features including light absorption via pigmentation, polarity-driven fluid transport, and phagocytosis. With this method, we achieve a highly efficient and easily scalable differentiation without the need for mechanical isolation or enrichment methods, generating RPE cultures applicable for in vitro studies.

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:The traditional method for studying cancer in vitro is to grow immortalized cancer cells in two-dimensional (2D) monolayers on plastic. However, many cellular features are impaired in these unnatural conditions and big alterations in gene expression in comparison to tumors have been reported. Three-dimensional (3D) cell culture models have become increasingly popular and are suggested to be better models than 2D monolayers due to improved cell-to-cell contacts and structures that resemble in vivo architecture. The aim of this study was to develop a simple high-throughput 3D drug screening method and to compare drug responses in JIMT1 breast cancer cells when grown in 2D, in polyHEMA coated anchorage independent 3D models and in Matrigel on-top 3D cell culture models. We screened 102 compounds with multiple concentrations and biological replicates for their effects on cell proliferation. The cells were either treated immediately upon plating or they were allowed to grow in 3D for four days prior to the drug treatment. Big variations in drug responses were observed between the models indicating that comparisons of culture model influenced drug sensitivities cannot be made based on effects of a single drug. However, we show with the 63 most prominent drugs that, in general, JIMT1 cells grown on Matrigel were significantly more sensitive to drugs than cells grown in 2D cultures, while responses of cells grown in polyHEMA resembled those of 2D. Furthermore, comparison of gene expression profiles of the cell culture models to xenograft tumors indicated that cells cultured in Matrigel and as xenografts most closely resembled each other. In this study we also suggest that 3D cultures can provide a platform for systematic experimentation of larger compound collections in a high-throughput mode and be used as alternatives for traditional 2D screens towards better comparability to in vivo state. Gene expression analysis of JIMT1 breast cancer cells cultured as xenografts for 43 days, in two dimensional cultures for seven days (2D7d), in polyHEMA three dimensional cell culture models for four and seven days (PH7d and PH7d), and in Matrigel three dimensional cultures for four and seven days (MG4d and MG7d). Two biological replicates was included for each sample.

Project description:Intrahepatic cholangiocarcinoma (ICC) is one of the most lethal liver cancers. The late diagnosis as well as the resistance to chemotherapy concurred to the scarce outfit of this malignancy. Even the improvement of the knowledge and, as consequence, of the broad spectrum of alternative therapies available (i.e. targeted, immune checkpoint inhibitors), the survival and the quality of life remain poor. The phenomenon of resistance is not still clear. Here, we established one gemcitabine, GEM, (the standard therapy in ICC) resistant cell line, named MTCHC01R1.5, obtained by a gradual exposure to GEM for 9 months (up to 1.5 µM) of the sensible counterpart MT-CHC01. We biologically and molecularly characterized this cell line comparing its behavior with its parental cell line. The drug resistance is irreversible, even if cells are treated with high doses of GEM. They grew slowly, both in vitro and in vivo, and no differences are highlighted in terms of migration and invasion. GEM resistance promoted a multi drug resistance development, but the drug prediction analysis showed that paclitaxel and doxycycline could overcome GEM resistance, as confirmed by cell viability assay. There is a global enrichment of up-regulated genes involved in the regulation of cell cycle and in DNA related process. The down-regulated genes are involved in response to stimuli, and xenobiotic metabolism, and angiogenesis. A deregulation of more than 20 genes related to drug resistance and epithelial to mesenchymal transition (EMT) was found. The trend in expression of 9 genes related to resistance is confirmed in a primary cell culture. In conclusion, we characterized a new Italian GEM resistance ICC model which could be exploited either to study the mechanism of resistance or to explore new therapies.

Project description:The traditional method for studying cancer in vitro is to grow immortalized cancer cells in two-dimensional (2D) monolayers on plastic. However, many cellular features are impaired in these unnatural conditions and big alterations in gene expression in comparison to tumors have been reported. Three-dimensional (3D) cell culture models have become increasingly popular and are suggested to be better models than 2D monolayers due to improved cell-to-cell contacts and structures that resemble in vivo architecture. The aim of this study was to develop a simple high-throughput 3D drug screening method and to compare drug responses in JIMT1 breast cancer cells when grown in 2D, in polyHEMA coated anchorage independent 3D models and in Matrigel on-top 3D cell culture models. We screened 102 compounds with multiple concentrations and biological replicates for their effects on cell proliferation. The cells were either treated immediately upon plating or they were allowed to grow in 3D for four days prior to the drug treatment. Big variations in drug responses were observed between the models indicating that comparisons of culture model influenced drug sensitivities cannot be made based on effects of a single drug. However, we show with the 63 most prominent drugs that, in general, JIMT1 cells grown on Matrigel were significantly more sensitive to drugs than cells grown in 2D cultures, while responses of cells grown in polyHEMA resembled those of 2D. Furthermore, comparison of gene expression profiles of the cell culture models to xenograft tumors indicated that cells cultured in Matrigel and as xenografts most closely resembled each other. In this study we also suggest that 3D cultures can provide a platform for systematic experimentation of larger compound collections in a high-throughput mode and be used as alternatives for traditional 2D screens towards better comparability to in vivo state.

Project description:We found that the isolated and expanded MCAM positive vCAF subpopulations significantly accelerated ICC growth. To further investigate the effect of vCAF on ICC cells (GFP-FRH or GFP-RBE), we co-cultured the vCAF with GFP ICC cells or ICC cells alone for seven days, then we sorted the GFP-FRH or GFP-RBE cells via FACS and conducted transcriptome microarray analysis of GFP ICC cells alone or vCAF co-cultured GFP-ICC cells.

Project description:As genomic analysis technology has advanced, it has become possible to sub-classify intrahepatic cholangiocarcinoma (ICC) at the histological or molecular level. However, there are no truly representative models of ICC subtypes for use in studying developmental differences, carcinogenesis, and personalized drug response. Here, we sought to verify recent suggested two subgroup of ICC in organoids model, compare the characteristics between LD and SD type of ICC, and find the type-specific gene expression profile and targetable pathway as a therapeutic target. ICC organoids from 16 patients pathologically diagnosed with cholangiocarcinoma were prepared according to a previously established organoid culture protocol. ICC patients were subclassified into small-duct (SD) type and large-duct (LD) type according to histological characteristics and S100P, N-cadherin, and CD56 expression. ICC organoids were successfully established within one month and exhibited a morphology similar to that of their matching primary cancer. LD- and SD-type organoids exhibited histologic phenotypes and staining patterns characteristic of the corresponding ICC subtypes. ICC organoids showed high concordance of somatic mutations with primary tumors. Unsupervised principal component analysis clustering effectively separated each type of ICC. Differential gene expression revealed significant enrichment on KRAS, TGFβ and ERBB2 signaling pathways in LD-type compared with SD-type ICC (P<0.05). Gene set enrichment analysis further demonstrated that the cholangiocarcinoma class 2 signature, defined by Andersen et al., was significantly enriched in the LD-type (enrichment score=2.19, P<0.001). A protein-protein interaction network analysis identified ZNF217 as a significant hub protein (odds ratio=4.96, P=0.0105). We successfully performed prospective modeling of histological subtype specification using patient-derived ICC organoids. Moreover, gene expression profiling of ICC organoids enabled identification of type-specific targetable pathways.