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:Highly invasive integrin and protease-independent amoeboid migration is often employed by cancer cells at the invasive front, though little is known about the transcriptomic changes underlying the switch to an amoeboid migratory mode. Using a metastatic melanoma cell line expressing photoconvertible Dendra2 protein (WM983c-D2), tumour spheroids were cultured in 3D collagen matrices and imaged over time. Spheroids grown from WM983c-D2 cells generate cells of three distinct phenotypes: 1) compact, non-invading cells organised at the spheroid surface with no visual cell protrusions, hereafter termed ‘epithelial’; 2) cells still attached to the spheroid periphery that have commenced tumour escape, exhibiting cellular protrusions and an elongated phenotype, hereafter termed ‘escaping’; 3) singly migrating cells exhibiting a rounded phenotype and no lamellipodia consistent with amoeboid cell migration, hereafter termed 'amoeboid'. Individual amoeboid and escaping cells, as well as groups of epithelial cells at the spheroid edge were photoconverted and single cell sorted via FACS following enzymatic digestion of the collagen matrix. 10 Epithelial, 12 escaping and 13 amoeboid cells were subjected to scRNA-seq and differential expression analyses in order to identify changes in gene expression as melanoma cells convert from a non-invasive epithelial state to invasive amoeboid cells.

Project description:Interaction between stromal cells and the tumor greatly influences tumor initiation and progression. Cancer-associated fibroblasts (CAFs) are the major component of tumor stroma and play a key role in ovarian cancer (OC) cells adhesion and metastasis. CAFs were found abundantly in primary tumor and metastases, as well as in malignant ascites of high grade serous OC patients, underscoring that CAFs modulate OC cells phenotype and facilitate disease exacerbation along OC progression. Studies of CAFs exertion on OC mainly focused on the influence of CAFs conditioned medium (CM) influence of tumor cells phenotype, while ignoring the fact that CAFs are supposed to be in intimate contact with neoplastic cells in tumor mass, and that CAFs also form compact heterotypic spheroids with ascitic tumor cells in malignant ascites. We hypothesized that uncovering the underlying molecules that mediate tumor cells binding with CAFs could aid in developing measures destroying the pro-carcinogenic heterotypic spheroids in malignant ascites. In this study, gene expression profiling was completed for individual SKOV3, and magnetic sorted SKOV3 cells that form heterotypic spheroids with 4 cases of high grade serous OC derived CAFs. By comparing the expression data of SKOV3 cells in individual group with that in spheroid group, we identified a set of differential expressed genes. This study revealed the heterogeneity of ascitic tumor cells and raised potent therapeutical targets in destroying of the heterotypic spheroids in malignant ascites of OC. We used microarrays to profile the mRNA expression of SKOV3 tumor cells that could or not form heterotypic spheroids with CAFs, in order to identify molecules that potentially mediate the combination between tumor cells and CAFs.

Project description:Dissection of melanoma heterogeneity through gene expression profiling has led to the identification of two major phenotypes, conventionally defined as “MITF high / proliferative” and “AXL high / invasive”. Tumors or single melanoma cells characterized by a predominant AXL-related gene program show enhanced expression of sets of genes involved in motility, invasion and regulation of epithelial-mesenchymal transition (EMT), while these genes are downregulated in tumors or cells with a predominant MITF-related gene program. The activation of the AXLhi/MITFlo invasive gene program in melanoma is characterized by aberrant expression of transcription factors (TFs) involved in the embryonic EMT process. Additional master genes involved in promoting melanoma growth and invasive state have been identified within the family of epigenetic regulators. Two of these genes, RNF2 and EZH2, components of the polycomb repressive complexes 1 and 2, act by epigenetically silencing tumor suppressors that in turn regulate the invasive and EMT-like phenotype of melanoma cells. Additional master genes involved in promoting melanoma growth and invasive state have been identified within the family of epigenetic regulators. Two of these genes, RNF2 and EZH2, components of the polycomb repressive complexes 1 and 2, act by epigenetically silencing tumor suppressors that in turn regulate the invasive and EMT-like phenotype of melanoma cells. Here we provide evidence for a new actionable pathway that controls melanoma EMT-like/invasive phenotype. We show that in MITFlo melanomas, the TF NFATc2 controls the EMT-like transcriptional program, the invasive ability of neoplastic cells, as well as in-vitro and in-vivo growth, through a pathway that functionally links c-myc to FOXM1 and EZH2. Targeting of NFATc2, FOXM1 or EZH2 inhibited melanoma migratory and invasive activity. Moreover, pharmacological co-targeting of NFATc2 and EZH2 promoted apoptosis of BRAF-mutant melanomas with intrinsic resistance to BRAF inhibition.

Project description:Tumor angiogenesis is regarded as a promising target for limiting cancer progression because tumor-associated vasculature supplies blood and provides a path for metastasis. Thus, in vitro recapitulation of vascularized tumors is critical to understand the pathology of cancer and identify the mechanisms by which tumor cells proliferate, metastasize, and respond to drugs. In this study, we microengineered a vascularized tumor spheroid (VTS) model to reproduce the pathological features of solid tumors. We first generated tumor cell-EC hybrid spheroids with self-assembled intratumoral vessels, which enhanced the uniformity of the spheroids and peritumoral angiogenic capacity compared to spheroids comprised only with cancer cells. Notably, the hybrid spheroid also exhibited expression profiles associated with aggressive behavior. The blood vessels sprouting around the hybrid spheroids on the VTS chip were interconnected with intratumoral vessels and displayed the distinctive characteristics of leaky tumor vessels. With the VTS chip showing a progressive tumor phenotype, we validated the suppressive effects of axitinib on tumor growth and angiogenesis, which depended on exposure dose and time, highlighting the significance of tumor vascularization to predict the efficacy of anticancer drugs. Ultimately, we effectively induced both lymphangiogenesis and angiogenesis around the tumor spheroid by promoting interstitial flow. Thus, our VTS model is a valuable platform with which to investigate the interactions between tumor microenvironments and explore therapeutic strategies in cancer.

Project description:Detachment of melanoma and survival under anchorage-independency were recognized as initial step of tumor metastasis. Our previous studies showed altered gene expression contributed to loss of cell invasiveness, enhanced chemosensitivity, and enhanced subcutaneous tumor formation. In this study, we demonstrated that melanoma cell detachment altered vascular phenotype of melanoma metastases through disruption of expression axis of aminopeptidase-N/syndecan-1/integrin beta4, which would contribute to melanoma heterogeneity.

Project description:Full title: Comprehensive Characterization of Three-Dimensional Models for Prostate Cancer Growth and Invasion in Laminin-rich Extracellular Matrix Prostate Cancer (PrCa) cells undergo acinar morphogenesis and spheroid formation in three-dimensional (3D) culture, supported by laminin-rich extracellular matrix (lrECM, Matrigel). We developed miniaturized 3D model systems that facilitate investigation of morphogenesis and invasion of normal and PrCa cell lines in lrECM. Primary and non-transformed cell lines formed round structures with strong cell-cell contacts and epithelial polarization, lumen and a complete basal lamina (BL). In contrast, most PrCa cell lines formed either defective, “mass” spheroids with incomplete BL, or invasive “stellate” structures. The bioinformatic analyses of genome-wide mRNA expression data revealed massive alteration of key functional and signaling pathways in 3D cultures, with lipid and steroid metabolism, epigenetic reprogramming, and differentiation-related transcription factors induced across all cell lines by lrECM. In invasive cells, AKT, PI3Kinase, mTOR, and hedgehog signaling pathways were most highly activated, validated by small molecule inhibitors compounds specifically targeting key regulatory molecules. Compounds against AKT and PI3kinase pathways were significantly more effective in invasive cells, compared to mass or round/normal phenotype spheroids, and monolayer culture. A severe morphologic conversion was observed in PC-3 and PC-3M cells, transforming initially round, normal-appearing epithelial spheroids into rapidly invading cell masses. Markers for EMT (epithelial-mesenchymal transition) were highly expressed already in early stage, round spheroids prior to invasive conversion, and were not further increased in invasive cells. This indicates that PrCa cells can display extraordinary plasticity. EMT may be involved in providing a metastable genotype that allows morphological transformation, but is not be required for invasive processes themselves. Total RNA was obtained from non-transformed prostate epithelial cells and prostate cancer cells cultured in monolayer and three-dimensional laminin-rich extracellular matrix (growth factor-reduced Matrigel).

Project description:Immortal spheroids were generated from fetal mouse intestine using the culture system developed to culture organoids from adult intestinal epithelium. Spheroids are made of a monostratified polarized epithelium displaying a poorly differentiated intestinal phenotype. The proportion of spheroids generated from intestinal explants progressively decreases from fetal to postnatal period, with a corresponding increase in production of organoids. Spheroid cells show indefinite self-renewing properties but exhibit a transcriptome strikingly different from that of adult intestinal stem cells reminiscent of incompletely caudalized progenitors. The receptor Lgr4, but not Lgr5, is essential for their growth. Trop2/Tacstd2 and Cnx43/Gja1, two markers highly enriched in spheroids, are expressed throughout the E14 intestinal epithelium. Comparison of in utero and neonatal lineage tracing using Cnx43-CreER and Lgr5-CreERT2 mice identified spheroid-generating cells as developmental progenitors involved in generation of the prenatal intestinal epithelium. Ex vivo, spheroid cells have the potential to differentiate into organoids, thus qualifying them as a new type of intestinal stem-like cells. Two-channel microarray experiments were performed from spheroid/organoid pairs isolated each from a given embryo. Following initial seeding of small intestine from a given embryo/mouse (at E16, E18 or P0), spheroids and organoids were selectively picked up for each animal and replated for 3 passages to reach sample homogeneity. Hybridization was performed on the 4 independent pairs with dye-swap.

Project description:Epithelial ovarian cancer (EOC) is a high-risk cancer presenting with heterogeneous tumors. The high incidence of EOC metastasis from primary tumors to nearby tissues and organs is a major driver of EOC lethality. We used cellular models of spheroid formation and re-adherence to investigate cellular signaling dynamics in each step toward EOC metastasis. In our system, adherent cells model primary tumors, spheroids formation represents the initiation of metastatic spread, while re-adherent spheroid cells represent secondary tumors. Proteomic and phosphoproteomic analyses show that spheroid cells are hypoxic and show markers for cell cycle arrest. Aurora kinase B (AURKB) abundance and downstream substrate phosphorylation are significantly reduced in spheroids and re-adherent cells, explaining their cell cycle arrest phenotype. The proteome of re-adherent cells is most similar to spheroids, yet greater changes in the phosphoproteome show that spheroid cells stimulate Rho-associated kinase 1 (ROCK1) mediated signaling, which controls cytoskeletal organization. In spheroids, we found significant phosphorylation of ROCK1 substrates that were reduced in both adherent and re-adherent cells. Application of the ROCK1-specific inhibitor Y-27632 to spheroids increased the rate of re-adherence and spheroid density. The data suggest ROCK1 inhibition increases EOC metastatic potential. We identified novel pathways controlled by AURKB and ROCK1 as major drivers of metastatic behavior in EOC cells. Our data show that phosphoproteomic reprogramming precedes proteomic changes that characterize spheroid re-adherence in EOC metastasis.

Project description:Melanoma is a highly metastatic tumor type responsible of the large majority of the skin cancer-related deaths. Melanoma cells recapitulate the migratory and invasive nature of neural crest stem cells from which melanocytes arise. However, the mechanisms by which these developmental programs confer melanoma cells with more aggressive properties are not understood. Here we provide evidence for an epigenetically regulated developmental program that is aberrantly re-activated by melanoma cells to aid in the metastatic process. We reasoned that studying molecular changes occurring during the ontogeny of melanocytes from progenitor neural crest cells (NCC), and identifying developmental programs retained or re-gained by melanoma cells, could reveal crucial processes that modulate melanoma aggressiveness. Here we describe a novel mechanism that controls the activity of a transcriptional regulator of human neural crest, the Nuclear Receptor Subfamily 2 Group F, Member 2 (NR2F2). We find that highly localized DNA methylation acts as an on/off switch that controls the expression of a truncated NR2F2 isoform (NR2F2-Iso2) from an alternative transcription start site during NCC to melanocyte differentiation. We show that melanoma cells co-opt this developmental program by decreased DNA methylation and re-expression of NR2F2-Iso2 to promote melanoma metastasis. NR2F2-Iso2 regulates the transcriptional activity of the full length NR2F2 isoform 1 by impairing its binding to chromatin, which results in altered expression of NCC and differentiation genes. Our data demonstrate that epigenetic reactivation of NR2F2 isoform 2 promotes melanoma metastasis, which could be targeted for therapeutic purposes.