Project description:Summary: Melanoma spheroids grown under neural crest cell conditions are highly plastic migratory/invasive tumor cells endowed with immunomodulator function Background: The aggressiveness of melanoma tumors is likely to rely on their well-recognized heterogeneity and plasticity. Melanoma comprises multi subpopulations of cancer cells some of which may possess stem cell-like properties supporting the notion of plasticity. Although useful for certain tumors, the use of the sphere-formation assay to identify stem cell-like or tumor initiating cells subpopulations in human melanoma has been recently challenged. Our study reveals that this assay predicts a functional phenotype associated with aggressive behavior of tumor cells. Methodology/Principal Findings: We analyzed the molecular and functional phenotypes of melanoma spheroids formed in neural crest cell medium. Whether from metastatic (SLM8) or advanced primary (Mela1) tumors, spheroid cells expressed melanoma-associated markers. They displayed higher capacity to differentiate along mesenchymal lineages, and showed enhanced expression of SOX2, NANOG, KLF4, and/or OCT4 transcription factors, but not extensive self-renewal or enhanced tumorigenicity when compared to their adherent counterparts. To determine whether melanoma spheroids in our model could predict a molecular or functional phenotype, we performed gene expression profiling experiments using Affymetrix microarrays. Gene expression profiling attributed a neural crest cell signature to these spheroids and indicated that a migratory/invasive and immune-function modulating program could be associated with these cells. In vitro assays confirmed that these spheroids are endowed with enhanced migratory/invasive capacities. In immune activation assays, spheroid cells elicited a poorer allogenic response from immune cells and inhibited mitogen-dependent T cells activation and proliferation more efficiently than their adherent counterparts. Thus, our findings reveal novel immune-modulator function of melanoma spheroid cells and suggest specific roles for these spheroids in invasion and in evasion of antitumor immunity. Conclusion/Significance: The association of a more plastic, invasive and evasive, thus a more aggressive tumor phenotype with melanoma spheroid cells reveals a previously unrecognized aspect of tumor cells expanded as spheroid cultures. While of limited efficiency for melanoma initiating cell identification, our melanoma spheroid model predicted aggressive phenotype and could therefore, be constructive to investigate melanoma aggressiveness, relevant to patients and clinical transferability. 12 Total samples were analyzed: SLM8 adherent (SLMA) and spheroids (SLMS) cells, and Mela1 adherent (MelaA) and spheroid (MelaS) cells, all performed in triplicates. Paired statistical analyses were performed using Student's paired t-test on the gene signal intensities (gene level) and results were considered statistically significant at p-values <=0.05 and fold-change >=1.5.

Project description:In vertebrates, all cells except circulating blood cells must adhere to support their normal growth and functions. The adherence to extracellular matrix and/or other cells is critical and adherent cells placed in non-adherent conditions either die or form multicellular spheroids. Placing cells in non-adherent conditions has been used to induce differentiation in teratocarcinoma cells and more recently to form organoids . Because of such important consequences induced by cell adhesion on cell growth and function, the transition between adherent and non-adherent states is rather rare. There are however physiological situations, such as blood cells diapedesis, during which cells that circulate into the blood stream must adhere to the endothelial cells and cross the endothelial barrier to reach target tissues. Another example of transition, from an adherent to a non-adherent state, is observed in the metastasic process, where cells detach from the tumor mass and circulate in the blood and lymphatic vasculature prior to reattaching and extravasating to colonize distant organs. The comparative analysis of the only effects of adherence on cellular functions is complicated by the fact that in many study models the acquisition or loss of adherence induces major alterations in cell physiology that would obscure the effects of the adherence itself. For example, P19 teratocarcinoma cells differentiate in suspension spheroids while they do not in adhering conditions. In this context, the comparison between spheroids and adherent cells would not be a comparison between adherent and non-adherent cells, but between differentiated cells adhering between them and undifferentiated cells adhering on plastic. Mouse macrophage cell lines represent one of the rare experimental models that may be suitable to compare the adherent and non-adherent states. Indeed, they grow equally well under adherent and non-adherent conditions and keep their differentiated functions under both conditions. We therefore decided to use this model to analyze the changes between the adherent and the non-adherent state using a broad approach, based on proteomics.

Project description:Cell-based approaches utilizing autologous human renal cells require their isolation, expansion in vitro and reintroduction back into the host for renal tissue regeneration. Nevertheless, human kidney epithelial cells (hKEpC) lose their phenotype, dedifferentiate and assume the appearance of fibroblasts after relatively few passages in culture. We hypothesized that growth conditions may influence hKEpC phenotype and function. hKEpC retrieved from human nephrectomy tissue samples showed the ability to reproducibly form kidney-spheres when grown in suspension culture developed in non-adherent conditions. Genetic labeling and time-lapse microscopy indicated, at least in part, the aggregation of hKEpC into 3D-spheroids rather than formation of pure clonally expanded spheres. Characterization of hKEpC spheroids by real-time PCR and FACS analysis showed up-regulation of some renal developmental and 'stemness' markers compared to monolayer and mostly an EpCAM+CD24+CD133+CD44+ spheroid cell phenotype. Oligonucleotide microarrays which were used to identify global transcriptional changes accompanying spheroid formation, showed predominantly up-regulation of cell matrix/cell contact molecules and cellular biogenesis processes and down-regulation of cell cycle, growth and locomotion. Accordingly, hKEpC spheroids proliferated slowly as indicated by low Ki-67 staining, but when grafted in low cell numbers onto the chorioallantoic membrane (CAM) of the chick embryo, they exclusively reconstituted various renal tubular epithelia. Moreover, efficient generation of kidney spheroids was observed after long-term monolayer culture resulting in re-establishment of tubulogenic capacity upon CAM grafting. Thus, generation of a specialized quiescent niche in hKEpC spheroids may provide a functional benefit for kidney-derived cells in vivo. 6 samples, 3 adherent and 3 spheroids samples

Project description:This SuperSeries is composed of the following subset Series: GSE14818: Gene expression analysis of glioblastoma spheroid cultures I GSE14819: Array CGH analysis of glioblastoma serum grown adherent cultures GSE14820: Array CGH analysis of glioblastoma cell lines GSE14821: Array CGH analysis of single spheroids from glioblastoma spheroid cultures GSE14822: Array CGH analysis of glioblastoma spheroid cultures GSE14823: Array CGH analysis of glioblastomas GSE16666: Gene expression analysis of glioblastoma spheroid cultures II Refer to individual Series

Project description:Summary: Melanoma spheroids grown under neural crest cell conditions are highly plastic migratory/invasive tumor cells endowed with immunomodulator function Background: The aggressiveness of melanoma tumors is likely to rely on their well-recognized heterogeneity and plasticity. Melanoma comprises multi subpopulations of cancer cells some of which may possess stem cell-like properties supporting the notion of plasticity. Although useful for certain tumors, the use of the sphere-formation assay to identify stem cell-like or tumor initiating cells subpopulations in human melanoma has been recently challenged. Our study reveals that this assay predicts a functional phenotype associated with aggressive behavior of tumor cells. Methodology/Principal Findings: We analyzed the molecular and functional phenotypes of melanoma spheroids formed in neural crest cell medium. Whether from metastatic (SLM8) or advanced primary (Mela1) tumors, spheroid cells expressed melanoma-associated markers. They displayed higher capacity to differentiate along mesenchymal lineages, and showed enhanced expression of SOX2, NANOG, KLF4, and/or OCT4 transcription factors, but not extensive self-renewal or enhanced tumorigenicity when compared to their adherent counterparts. To determine whether melanoma spheroids in our model could predict a molecular or functional phenotype, we performed gene expression profiling experiments using Affymetrix microarrays. Gene expression profiling attributed a neural crest cell signature to these spheroids and indicated that a migratory/invasive and immune-function modulating program could be associated with these cells. In vitro assays confirmed that these spheroids are endowed with enhanced migratory/invasive capacities. In immune activation assays, spheroid cells elicited a poorer allogenic response from immune cells and inhibited mitogen-dependent T cells activation and proliferation more efficiently than their adherent counterparts. Thus, our findings reveal novel immune-modulator function of melanoma spheroid cells and suggest specific roles for these spheroids in invasion and in evasion of antitumor immunity. Conclusion/Significance: The association of a more plastic, invasive and evasive, thus a more aggressive tumor phenotype with melanoma spheroid cells reveals a previously unrecognized aspect of tumor cells expanded as spheroid cultures. While of limited efficiency for melanoma initiating cell identification, our melanoma spheroid model predicted aggressive phenotype and could therefore, be constructive to investigate melanoma aggressiveness, relevant to patients and clinical transferability.

Project description:Cancer progression and wound healing share some characteristics. Most colorectal cancers are differentiated adenocarcinomas that maintain three-dimensional structures to some extent. Hence, disruption of the architecture can provoke remodeling similar to the remodeling of normal intestinal epithelium. We used our recently developed three-dimensional culture system to investigate the response of cancer cell spheroids to mechanical disruption. Specifically, we developed a protocol for homogenous disruption of the spheroids that maintained the cell-cell contacts. After disruption, 9 spheroids from 9 patient samples reformed within a few hours, and 2 showed accelerated spheroid growth. Stemness increased after spheroid disruption, as assessed by marker expression, spheroid forming capacity, radiation sensitivity, and tumorigenesis. The spheroid-forming capacity increased in 6 of 11 spheroids. The disruption signature, as determined by gene expression profiling, supported the incidence of remodeling and predicted the prognosis of the colorectal cancer patients. WNT and HER3 signaling was increased in the reformed spheroids, and suppression of these signaling pathways attenuated the increases in growth and stemness after disruption. Thus, disorganized architecture in patient tumors might reflect the processes of disruption and subsequent remodeling and represent a cause rather than simply a consequence of malignancy progression. Gene expression in cancer tissue-originated spheroids (CTOSs) was measured at pre, 6 hr, 24 hr, and 4 days after mechanical disruption. One experiment was performed at each time point.

Project description:Cell-based approaches utilizing autologous human renal cells require their isolation, expansion in vitro and reintroduction back into the host for renal tissue regeneration. Nevertheless, human kidney epithelial cells (hKEpC) lose their phenotype, dedifferentiate and assume the appearance of fibroblasts after relatively few passages in culture. We hypothesized that growth conditions may influence hKEpC phenotype and function. hKEpC retrieved from human nephrectomy tissue samples showed the ability to reproducibly form kidney-spheres when grown in suspension culture developed in non-adherent conditions. Genetic labeling and time-lapse microscopy indicated, at least in part, the aggregation of hKEpC into 3D-spheroids rather than formation of pure clonally expanded spheres. Characterization of hKEpC spheroids by real-time PCR and FACS analysis showed up-regulation of some renal developmental and 'stemness' markers compared to monolayer and mostly an EpCAM+CD24+CD133+CD44+ spheroid cell phenotype. Oligonucleotide microarrays which were used to identify global transcriptional changes accompanying spheroid formation, showed predominantly up-regulation of cell matrix/cell contact molecules and cellular biogenesis processes and down-regulation of cell cycle, growth and locomotion. Accordingly, hKEpC spheroids proliferated slowly as indicated by low Ki-67 staining, but when grafted in low cell numbers onto the chorioallantoic membrane (CAM) of the chick embryo, they exclusively reconstituted various renal tubular epithelia. Moreover, efficient generation of kidney spheroids was observed after long-term monolayer culture resulting in re-establishment of tubulogenic capacity upon CAM grafting. Thus, generation of a specialized quiescent niche in hKEpC spheroids may provide a functional benefit for kidney-derived cells in vivo.

Project description:Tumor microenvironments present significant barriers to anti-tumor agents. Molecules involved in multicellular tumor microenvironments, however, are difficult to study ex vivo. Here, we generated a matrix-free tumor spheroid model using the NCI-H226 mesothelioma cell line and compared the gene expression profiles of spheroids and monolayers using microarray analysis. Microarray analysis revealed that 142 probe sets were differentially expressed between tumor spheroids and monolayers. Gene ontology analysis revealed that upregulated genes were primarily related to immune response, wound response, lymphocyte stimulation and response to cytokine stimulation, whereas downregulated genes were primarily associated with apoptosis. Among the 142 genes, 27 are located in the membrane and related to biologic processes of cellular movement, cell-to-cell signaling, cellular growth and proliferation and morphology. Western blot analysis validated elevation of MMP2, BAFF/BLyS/TNFSF13B, RANTES/CCL5 and TNFAIP6/TSG-6 protein expression in spheroids as compared to monolayers. Thus, we have reported the first large scale comparison of the transcriptional profiles using an ex vivo matrix-free spheroid model to identify genes specific to the three-dimensional biological structure of tumors. The method described here can be used for gene expression profiling of tumors other than mesothelioma. We generated a matrix-free tumor spheroid model using the NCI-H226 mesothelioma cell line and compared the gene expression profiles of spheroids and monolayers using microarray analysis. Microarray analysis experiments were performed in triplicates. A total of six samples (three for monolayers and three for spheroids) were analyzed.

Project description:More than 70% of patients with epithelial ovarian cancer (EOC) are diagnosed with peritoneal metastasis and ascites, which is the accumulation of intraperitoneal fluid containing non-malignant cells. However, the interactions between EOC and non-malignant cells before the development of peritoneal metastasis remain unclear. This study investigated the mechanism by which EOC cells survive through interactions with the surrounding cells in ascites. Whole EOC spheroids were observed, and their invasion into collagen layers and mesothelial monolayers was examined. RNA sequencing revealed the molecular mechanisms associated with aggressiveness of EOC cells. In malignant ascites, almost 100% of EOC cells were spheroids, 60% of which contained mesothelial cells. EOC cells quickly generated aggregated spheroids with mesothelial cells, and these aggregated cancer-mesothelial spheroids (ACMS) rapidly invaded collagen or mesothelial layers. Mesothelial cells forming ACMS initiated the invasion, with EOC cells following the route created by the mesothelial cells. RNA sequence revealed dramatically RNA expression changes in mesothelial cells, whereas the changes in EOC cells were relatively small. TGF-β1-stimulated mesothelial cells showed increased invadopodia formation along with fascin-1 upregulation. These findings suggest that EOC cells alter gene expression in mesothelial cells through ACMS formation, which explains the rapid spread of EOC in the abdominal cavity.

Project description:Cancer progression and wound healing share some characteristics. Most colorectal cancers are differentiated adenocarcinomas that maintain three-dimensional structures to some extent. Hence, disruption of the architecture can provoke remodeling similar to the remodeling of normal intestinal epithelium. We used our recently developed three-dimensional culture system to investigate the response of cancer cell spheroids to mechanical disruption. Specifically, we developed a protocol for homogenous disruption of the spheroids that maintained the cell-cell contacts. After disruption, 9 spheroids from 9 patient samples reformed within a few hours, and 2 showed accelerated spheroid growth. Stemness increased after spheroid disruption, as assessed by marker expression, spheroid forming capacity, radiation sensitivity, and tumorigenesis. The spheroid-forming capacity increased in 6 of 11 spheroids. The disruption signature, as determined by gene expression profiling, supported the incidence of remodeling and predicted the prognosis of the colorectal cancer patients. WNT and HER3 signaling was increased in the reformed spheroids, and suppression of these signaling pathways attenuated the increases in growth and stemness after disruption. Thus, disorganized architecture in patient tumors might reflect the processes of disruption and subsequent remodeling and represent a cause rather than simply a consequence of malignancy progression.