Project description:3D tumoroids have revolutionized in vitro/ex vivo cancer biology by recapitulating the complex diversity of tumors. While tumoroid provide new insights into cancer development and treatment response, several limitations remain. The tumor microenvironment, especially the immune system, strongly influences tumor development. Absence of immune cells in tumoroids may yield flawed conclusions. Macrophages, key players in tumor progression, pose integration challenges into tumoroid. In this study, we established three optimized and standardized methods for co-culturing human macrophages with breast cancer tumoroids: a semi-liquid model and two matrix-embedded models tailored for specific applications. Optimizing culture conditions, we tracked interactions and macrophage infiltration using flow cytometry and light sheet microscopy. Macrophages not only influenced tumoroid molecular profiles but also chemotherapy response. This underscores the importance of increasing the complexity of current 3D models to more accurately reflect in vivo conditions. The three models have different application and can be used in various ways.

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 compare gene expression patterns of MCF7 breast cancer cells when grown as xenografts, in 2D, in polyHEMA coated anchorage independent 3D models and in Matrigel on-top 3D cell culture models. Surprisingly small variations in gene expression patterns were observed between the models indicating that 3D and xenograft are not always that different from 2D cell cultures. Gene expression analysis of MCF7 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:Tumoroids, sometimes referred to as cancer organoids, are patient-derived cancer cells grown as 3D, self-organized multicellular structures that maintain key characteristics (e.g., genotype, gene expression levels) of the tumors from which they originated. These models have emerged as valuable tools for studying tumor biology, cytotoxicity, and the response of patient-derived cells to cancer therapies. However, the establishment and maintenance of tumoroids have historically been challenging, labor-intensive, and highly variable from lab to lab, hindering their widespread use. Here, we established patient-derived colorectal cancer tumoroid lines in OncoPro Tumoroid Culture Medium and performed RNA profiling of single cells from primary dissociated tumors and the corresponding tumoroids to compare the transcriptomic concordance in primary and OncoPro-derived samples.

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 compare gene expression patterns of MCF7 breast cancer cells when grown as xenografts, in 2D, in polyHEMA coated anchorage independent 3D models and in Matrigel on-top 3D cell culture models. Surprisingly small variations in gene expression patterns were observed between the models indicating that 3D and xenograft are not always that different from 2D cell cultures.

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:To conduct comparative transcriptomic analyses on normal or malignant prostate epithelial cells in response to tissue contextual changes, we cultured immortalized prostate epithelial cells or prostate cancer cells as cell monolayers or three-dimensional organoids and profiled their transcriptomes in respective culture contexts. RWPE-1 (immortalized prostate epithelial cells) and LNCaP cells (prostate cancer cells) were seeded on reconstituted basement membrane (rBM)-coated culture plastics or cultured within three-dimensional (3D) rBM gels. Total RNA samples were collected from cell monolayers or 3D cell clusters (formed at day 2) or acini or spheroids (formed at day 6) in the rBM culture, followed by global gene expression profiling.

Project description:To understand the molecular process associated with tissue morphogenesis of pancreatic epithelial cells, we profiled the transcriptomes of normal or malignant pancreatic organoids formed in three-dimenstional reconsitututed basement membrance (rBM). Cell monolayers cultured on rBM-coated culture plastics were used as controls. HPDE (immortalized pancreatic epithelial cells) and PANC-1 cells (pancreatic cancer cells) were seeded on reconstituted basement membrane (rBM)-coated culture plastics or cultured on top of three-dimensional (3D) rBM gels. Total RNA samples were collected from cell monolayers or 3D cell clusters (formed at day 2), pancreatic tubules or tumor spheroids (formed at day 6) in the rBM culture, followed by global gene expression profiling.

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:Transgenic mice and organoid models, such as three-dimensional tumoroid cultures, have emerged as powerful tools for investigating cancer development and targeted therapies. Yet, the extent to which these preclinical models recapitulate the cellular identity of heterogeneous malignancies, such as neuroblastoma (NB), remains to be validated. Here we characterize the transcriptional landscape of TH-MYCN tumors by single-cell RNA sequencing (scRNA-seq) and developed novel ex vivo tumoroids. We provide a comparative analysis with murine fetal adrenal gland and human NB, to decipher the heterogeneity, cell-cell interactions, and clinical relevance of these models. Integrated analysis with fetal adrenal samples confirmed that both TH-MYCN tumors and tumoroids closely mirror the cellular profiles of normal embryonic sympathoblasts and chromaffin cells. Comprehensive comparison between tumors from NB patients and TH-MYCN mice demonstrated similarities in adrenergic tumor cell composition. Through ex vivo tumoroid cultures, we demonstrated histological resemblance, and shared transcriptional profiles with originating TH-MYCN tumors and human NB. Importantly, we identified subpopulations within tumoroids that exhibit gene expression associated with poor NB patient survival. Notably, recurrent observations of a low-proliferative chromaffin phenotype connected to the highly proliferative sympathetic phenotype may suggest that pushing sympathoblasts into a chromaffin-like state may offer an interesting therapeutic strategy for NB. Together, this study not only deepens our understanding of the widely used transgenic mouse model but also introduces a novel ex vivo model that maintains critical adrenergic cell state identity, thereby enhancing its translational potential for NB research.

Project description:Development of a reliable method for human triple-negative breast cancer organotypic culture: Improving imaging and genomic studies in 3D cultures The primary objectives of this study are to develop an advanced three-dimensional cell culture system to better model the tumor microenvironment in triple-negative breast cancer (TNBC), analyze the differences in molecular and cellular behavior between two-dimensional (2D) and 3D cultures, and investigate the impact of these differences on key oncogenic signaling pathways, specifically PI3K and β-catenin.