Project description:3D spheroid culture to examine adaptive therapy response in invading tumor cells

Project description:Introduction: In vitro 3-dimension spheroid culture has been widely used as model to enrich CD44+CD24dim/- cancer stem cells with high ALDH1 activity. However, present of the CD24+ population in the 3D spheroid also requests further attention as this side-population of cells may response differently to drug treatment comparing to the cancer stem cells. Methods: In this study, CD24+ population from the MCF-7 spheroid was sorted and subjected to spheroid formation test, stem cell markers immunofluorescence, invasion/migration test, and microRNA expression profiling. MCF-7 CD24+ cells sorted from primary spheroid reform 3D spheroid after longer period of time associated with dim expression of surface SOX-2, CD44, CD49f and Nanog comparing to the primary spheroid. Results: Remarkably, the MCF-7 CD24+ cells was found with high expression of ALDH1 protein, which subsequently contributed to higher resistant against doxorubicin and cisplatin. MicroRNA profiling has shown that absent of cancer stem cell phenotypes were contributed by the downregulation of major cancer stem cells related pathways including Hedgehog, Wnt and MAPK signalling pathways. Besides, resistance of CD24+ cells was correlated to dyregulation of cell death pathway.

Project description:TGFbeta/TNFalpha treated spheroid A549 cultures are a model of the epithelial-mesenchymal transition (EMT). These experiments capture the changes in global gene expression that result from cells being induced to undergo EMT (3D control vs 3D treated), but also the differences in gene expression when A549 is grown in spheroid cultures (2D control vs 3D untreated). EMT is efficiently induced only in the spheroid culture model. A total of 8 samples are analyzed, corresponding to 4 conditions (2D control, 2D treated, 3D control, 3D treated) and 2 biological replicates.

Project description:TGFbeta/TNFalpha treated spheroid A549 cultures are a model of the epithelial-mesenchymal transition (EMT). These experiments capture the changes in global gene expression that result from cells being induced to undergo EMT (3D control vs 3D treated), but also the differences in gene expression when A549 is grown in spheroid cultures (2D control vs 3D untreated). EMT is efficiently induced only in the spheroid culture model.

Project description:Patient-derived cancer cells (PDCs) were established by three-dimensional (3D) spheroid culture from testicular germ cell tumor (GCT) specimens. Microarray expression analysis revealed that cancer stem-like cell-related genes were upregulated in 3D culture condition compared with two-dimensional (2D) culture condition.

Project description:The current objectives are to develop a 3D spheroid model that will allow us to better emulate placental invasion in vitro and to characterize the transcriptomic and functional outcomes.

Project description:3D spheroid cultures of primary human hepatocytes (PHH) are used in studies of hepatic drug metabolism and toxicity. However, the 3D spheroids are maintained under different conditions, with possible cofounding results. Here we performed an in-depth analysis of how various culture conditions influence 3D spheroids. Our aim was to find optimal conditions for the maintenance of a normal PHH phenotype.

Project description:Mesenchymal stem cells (MSC) are heterogeneous in morphology and transcriptome, resulting in varying therapeutic outcomes. In this study, we found that 3D spheroid culture of heterogeneous MSC, which have undergone conventional 2D monolayer culture for 5-6 passages, synchronized the cells into a uniform cell population with dramatically reduced cell size, and considerably increased levels of immunosuppressive genes and growth factors. Sc-RNA-Seq analysis of the cells revealed that 3D MSC consisted of 2 major cell subpopulations and both expressed high levels of immunosuppressive factors, compared to 6 subpopulations in 2D MSC. In addition, 3D MSC showed a greater suppressive effect on T cells. Moreover, intravenous infusion of a large dose of 3D MSC prior to Imiquimod (IMQ) treatment significantly improved psoriatic lesion. Thus, our results indicate that 3D spheroid culture reprograms heterogeneous mesenchymal stem cells into a uniform immunosuppressive phenotype and promises a novel therapeutic potential for inflammatory diseases.

Project description:Obvious advantages of 3D cell culture model are the cell morphology better reflecting tissue cell morphology, the formation of zones of i) active proliferation, ii) quiescent viable cell zone and iii) necrotic zone, as well as formation of nutrition, oxygen and drug gradients better reflecting cellular environment in tissue. Nevertheless the 3D cultures are a model still not resembling full complexity of tumor tissue environment in vivo. Few obvious limitations of 3D cell cultures as cancer research model are the lack of vasculature, host immune response and other cell-cell interactions that occur between cancer and stromal cells in tumors. Recognized advantages and limitations of the 3D cell culture models, however do not suggest directly the areas of cancer biology where 3D models could be applied with highest success. Hence detailed analysis at the molecular level of 2D/3D cell cultures and tumors in vivo are needed to unlock the power of 3D cell culture model. In order to elucidate which biological pathways of cancer cells in tumors are best resembled by the 3D cell culture model we have analyzed whole genome gene expression changes in mouse LLC1 cell line when cultured in 2D or laminin rich ECM 3D system. RNA was isolated 48h after growing in two different cell culture systems.

Project description:A capability to proliferate under the three-dimensional (3D) conditions is a characteristic property of cancer. Therefore, factors that regulate the 3D growth are considered rational targets for cancer therapy. We analyzed gene expression profile of human prostate cancer PC3 cells which were cultured in normal 2D conditions or in spheroid culture conditions (3D). The analysis suggested that the sheroid conditions would mimic a part of tumor-like 3D conditions. In addition, we analyzed genes regulated by TRIB1, a candidate oncogene in PC3 cells by comparing the gene expression profiles between control (shGFP)-treated and TRIB1 shRNA- (shTRIB1-1 and shTRIB1-2) treated cells. Our analysis identified a subset of genes that are downstream of TRIB1 in prostate cancer cells.