Project description:Background: Large-scale genomic analyses of patient cohorts have revealed extensive heterogeneity between individual tumors, contributing to treatment failure and drug resistance. In malignant melanoma, heterogeneity is thought to arise as a consequence of the differentiation of melanoma-initiating cells that are defined by cell-surface markers like CD271 or CD133. Results: Here we identified the nerve growth factor receptor (CD271) as a crucial determinant of melanoma cell tumorigenicity, stem-like properties, heterogeneity and plasticity. Stable shRNA mediated knock-down of CD271 in patient-derived melanoma cells abrogated their tumor-initiating and colony-forming capacity. A genome-wide expression profiling and gene-set enrichment analysis revealed novel connections of CD271 with melanoma-associated genes like CD133 and points to a neural crest stem cell (NCSC) signature lost upon CD271 knock-down. In a meta-analysis, we found CD271 linked to the neural crest specifier SOX10 and observed a shared set of 271 differentially regulated genes. To dissect the connection of CD271 and CD133 we analyzed 10 patient-derived melanoma-cell lines for cell-surface expression of both markers compared to established cell lines MeWo and A375. We found CD271+ cells in the majority of cell lines analyzed as well as in a set of 16 different patient-derived melanoma metastases. Strikingly, only 2/12 cell lines harbored a CD133+ sub-set that in addition comprised a fraction of cells of a CD271+/CD133+ phenotype. Those cells were found in the label-retaining fraction and in vitro deduced from CD271+ but not CD271 knock-down cells. Conclusions: Our present study provides a deeper insight into the regulation of melanoma cell properties and points CD271 out as a regulator of several melanoma-associated genes. Further, our data strongly suggest CD271 is a crucial determinant of stem-like properties of melanoma cells like colony-formation and tumorigenicity. For knock-down of CD271 (NGFR), melanoma cells were transfected with 2 M-BM-5g of each shRNA plasmid; #2: 5M-bM-^@M-^Y-ACAACCTCATCCCTGTCTATT-3M-bM-^@M-^Y; #3: 5M-bM-^@M-^Y-CCCGAGCACATAGA CTCCTTT-3M-bM-^@M-^Y and #4: 5M-bM-^@M-^Y-CCGAGCACATAGACTCCTTTA-3M-bM-^@M-^Y or control shRNA (shCtl 5M-bM-^@M-^Y-GGAATCTCATTCGATGCATAC-3M-bM-^@M-^Y; all from Quiagen) using Lipofectamine2000 (Invitrogen). Cells were selected with puromycin (10M-BM-5g/ ml) over a period of two weeks. Whole genome expression profiling of CD271k.d. cells (shRNA#4) and shCtl. cells was performed with three biological replicates. Illumina raw data of BeadChip HumanHT-12V4 platform were summarized via the BeadStudio without normalization and background correction. Follow-up processing was done via the R/Bioconductor environment employing packages lumi, limma and q-value. Data were normalized with quantile normalization. Genes were termed significantly differentially expressed when the average detection p-value of at least one case was < 0.05 the ratio was outside the interval [0.75,1.33], one of the p-values from limma test, Student's t-test, Welch test and Wilcoxon test was < 0.05. At least one of the q-values corresponding to one of these tests < 0.05.

Project description:Some cancers are thought to follow a cancer stem cell (CSC) model in which hierarchical and epigenetically determined relationships exist between phenotypically and functionally distinct cells within tumors. In melanoma, for example, CD271/p75/NGFR (nerve growth factor receptor) was found by some groups to be expressed in cells with enriched tumorigenic potential (Boiko et al., 2010; Civenni et al., 2011). However, these observations were not reproduced in highly efficient patient-derived xenograft (PDX) assays (Quintana et al., 2008), in which plastic, nonhierarchical relationships were proposed between CD271- and CD271+ cells (Quintana et al., 2010). Here we confirm that a CD271-based CSC model does not apply to melanoma, regardless of the PDX assay method used. In side-by-side testing of published PDX assays, no consistent differences were seen in CD271 expression or in PDX tumor formation from purified CD271- or CD271+ cells from patient melanomas. Analysis of CD271 in sixty-eight PDX tumors grown from CD271- or CD271+ cells revealed strikingly variable CD271 re-expression patterns, which were not consistent with stable hierarchical or plastic relationships between CD271-defined cell sub-populations. Genotyping of sibling PDX tumors showed extensive (28% - 48%) genomic copy number differences, which were also apparent (1.4% - 23%) between CD271- and CD271+ cells purified from each of four melanomas, revealing intra-tumoral genetic heterogeneity associated with CD271 expression. Thus, CD271 is not linked reproducibly to tumorigenic potential in melanoma, regardless of the method of melanoma cell isolation, and its expression appears driven by complex and unstable interactions between changing epigenetic and genetic states. Understanding of melanoma biology and the treatment of melanoma patients are unlikely to be advanced by applying a CD271-based CSC model to this disease.

Project description:Metastatic melanoma (MM) has a five-year survival rate of only 37%. The major causes of MM-related mortality are distant organ involvement and treatment resistance. These metastatic activities are often potentiated by the persistence of tumor-initiating cells (TICs) thriving in areas of hypoxia. To enhance therapy success, it is, thus, critical to understand MM TIC properties and devise MM TIC-specific treatment strategies. Our recent data suggest that MM cells have a distinct MM glycome signature characterized by fetal i-linear poly-N-acetyllactosamines (poly-LacNAc) and loss of I-branching enzyme β1,6 N-acetylglucosaminyltransferase 2 (GCNT2) that promote tumorigenicity. Whether hypoxia can instruct MM TIC development by modulating the MM glycome signature remains unknown. Here, comparative analysis of GCNT2 levels on patient melanoma cells and clinical outcome confirmed the relationship between loss of GCNT2 and poor patient survival. Moreover, MM cells with low GCNT2 showed elevated TIC marker expression and increased TIC potential, in vivo. Under hypoxia, MM cells further lost GCNT2 and I-branched poly-LacNAc expression and showed corresponding elevations in TIC markers and other glycome-related alterations. Galectin (Gal)-8, notably, was upregulated under hypoxia, preferred binding to i-linear poly-LacNAcs, increased TIC marker CD271, and was significantly elevated in sera of melanoma patients. Knockdown of Gal-8 in MM cells significantly decreased CD271 levels, even under hypoxia. Results from this investigation reveal a key role for hypoxia in enforcing the MM glycome signature and for Gal-8 as a pro-tumorigenic lectin and putative biomarker of MM.

Project description:CD133-positive colorectal cancer cells exhibit enhanced tumorigenicity over CD133-negative cells. The CD133+ cells are more interactive with and responsive to their stromal microenvironment because they also express the cognate receptors, such as CXCR4, for ligands produced by their neighboring carcinoma-associated fibroblasts, such as SDF-1 (stromal-derived growth factor). we isolated and separately cultured both the carcinoma cells and CAF from the same patient tumor. Three samples (CD133+, CD133-, Carcinoma associated fibroblasts) in triplicate for a total of 9 samples.

Project description:Nine heterogeneous melanoma cell lines including D10 and WM115 were studied for cancer stem cell characteristics in vitro. D10 cell line was the only cell line expressing the cancer stem cell marker CD133. Thus, gene expression profiling on CD133+ and CD133- D10 cells was carried out using Affymetrix GeneChips Human Genome U133A 2.0.

Project description:Metastatic melanoma is difficult to treat and is resistant to most current therapies. We hypothesized that stem cell related pathways may play a role in melanoma growth since stem cells and cancer cells share essential properties. Lately, the ABC transporter, ABCB5, as well as Cripto-1, CD20, CD133 and ABCG2 were used to isolate tumorigenic cells. Melanoma cells expressing MDR1 (ABCB1) were found in our lab to be enriched with ABCB5, Nanog, and Oct3/4 expression and were characterized by increased self-renewal capacity and anchorage independence. Melanoma significant heterogeneity was further demonstrated by Quintana et al. who found high prevalence of melanoma initiating cells when implanted into severely immunocompromised mice. Therefore, we took a more general approach in order to unravel pathways that are important for self-renewal and tumorigenicity of melanoma. We enriched for melanoma precursor cells (MPC) using culture conditions shown to enrich for normal melanocyte precursors. MPCs expressed higher levels of nanog and Oct3/4, as well as ABCB1 (MDR1) and ABCB5. Microarray analysis revealed deregulation of genes related to development, invasion, and cell cycle, in addition to upregulation of genes involved in Wnt signaling such as DVL3, DKK1, ID3, JAG1 and Wnt receptor, FZD7. We focused on Wnt signaling and found enrichment of FZD7+ cells in MPCs. Furthermore, FZD7+ cells co-expressed MDR1 and were enriched in highly tumorigenic xenograft parts when tested in mice. Inhibition of the Wnt pathway using secreted frizzled related protein-1 (sFRP1), resulted in attenuation of melanoma proliferation in a dose dependent manner demonstrating the important role of the Wnt pathway in melanoma growth and suggesting this pathway as a target for rational therapy. The canonical Wnt/beta-catenin pathway was not activated in MPC, as revealed using the Tcf Reporter assay. In contrast, we found increased of phosphorylated CAMKII, suggesting activation of the non-canonical Wnt pathway. Our data indicate that precursors within the melanoma tumor may acquire increased survival abilities that should be therapeutically targeted. In particular, we found that the non canonical wnt pathway and the wnt receptor FZD7 play a role in melanoma proliferation and tumorigenicity. We used specialized culture conditions that were found to enrich for normal melanoblasts, the precursors of melanocytes [7]. We found previously that these conditions result in a typical dedifferentiated unpigmented phenotype of melanoma cells in addition to enrichment of self-renewing cells [2]. Further characterization of these precursor cultures prepared from 6 human metastatic melanoma lesions revealed increased expression of stemness genes such as nanog and Oct3/4, as well as two recently reported melanoma precursor markers, MDR1 and ABCB5. Consistent with the normal melanoblast cultures we found increased expression of the melanoblast marker POU3F2 (BRN2, DCT). In contrast, the expression of MITF, a melanocyte differentiation marker was reduced by 85% in MPCs when compared with the primary culture (Figure 1a, relative expression of MPC vs. cells obtained from the same patient and cultured in regular conditions). Cell cycle analysis excluded death of differentiated cells as the cause of the precursor enrichment, as no apoptosis was evident (Figure 1b, c). Interestingly, there was an increase in S phase cells, indicating that these cells are undergoing divisions. Similarly, Wang et al. reported that CD133+ glioma cells have higher percentage of S phase cells as compared to CD133- cells [8]. We concluded that these culture conditions cause dedifferentiation of melanocytes in addition to enrichment by increased divisions of melanoma precursor cells. Therefore, we defined these cells as melanoma precursor cells (MPC). To reveal pathways of self-renewal in melanoma we have used two single cell clones that were prepared from primary human melanoma cultures obtained from a primary lesion. These cell clones differed in the self-renewal capacity (in the limiting dilution assay) and in their morphology: high self-renewal/polygonal vs low self-renewal/spindle shaped. We compared the two cell types described above, cultured in either regular RPMI-based media or culture conditions developed to enrich for normal melanocytic precursors (Cook AL, Donatien PD, Smith AG, Murphy M, Jones MK, et al. (2003) Human melanoblasts in culture: expression of BRN2 and synergistic regulation by fibroblast growth factor-2, stem cell factor, and endothelin-3. J Invest Dermatol 121: 1150-1159.), designated MPC (melanoma precursor cells) conditions, for two weeks.

Project description:Recent technological advances in single-cell genomics make it possible to analyze cellular heterogeneity of tumor samples. Here, we applied single-cell RNA-seq to measure the transcriptomes of 307 single cells cultured from three biopsies of three different patients with a BRAF/NRAS wild type, BRAF mutant/NRAS wild type and BRAF wild type/NRAS mutant melanoma metastasis, respectively. Analysis based on self-organizing maps identified sub-populations defined by multiple gene expression modules involved in proliferation, oxidative phosphorylation, pigmentation and cellular stroma. Gene expression modules had prognostic relevance when compared with gene expression data from published melanoma samples and patient survival data. We surveyed kinome expression patterns across sub-populations of the BRAF/NRAS wild type sample and found that CDK4 and CDK2 were consistently highly expressed in the majority of cells, suggesting that these kinases might be involved in melanoma progression. Treatment of cells with the CDK4 inhibitor palbociclib restricted cell proliferation to a similar, and in some cases greater, extent than MAPK inhibitors. Finally, we identified a low abundant sub-population in this sample that highly expressed a module containing ABC transporter ABCB5, surface markers CD271 and CD133, and multiple aldehyde dehydrogenases (ALDHs), as markers for melanoma stem or initiating cells. Patient-derived cultures of the BRAF mutant/NRAS wild type and BRAF wild type/NRAS mutant metastases showed more homogeneous single-cell gene expression patterns with gene expression modules for proliferation and ABC transporters. Taken together, our results describe an intertumor and intratumor heterogeneity in melanoma short-term cultures which might be relevant for patient survival, and suggest promising targets for new treatment approaches in melanoma therapy.

Project description:To identify candidate genes involved in enhanced tumorigenicity of CD133+ liver tumor-initiating cells Affymetrix Human Genome U133 Plus GeneChip 2.0 HCC cell line Huh7 was sorted into CD133+ and CD133- populations by flow cytometry

Project description:To identify candidate genes involved in enhanced tumorigenicity of CD133+ liver tumor-initiating cells Affymetrix Human Genome U133 Plus GeneChip 2.0 HCC cell line PLC8024 was sorted into CD133+ and CD133- populations by flow cytometry

Project description:Dysregulation of signaling networks controlling self-renewal and migration of developmental cell lineages is closely linked to the proliferative and invasive properties of tumors. Identification of such signaling pathways and their critical regulators is vital for successful design of effective targeted therapies against neoplastic tissue growth. The neurotrophin receptor (CD271/NGFR/p75/NTR) is a key regulator of the melanocytic cell lineage through its ability to mediate cell growth, survival, and differentiation. Using clinical melanoma samples, normal melanocytes and global gene expression profiling we have investigated the role of CD271 in rewiring signal transduction networks of melanoma cells during neoplastic transformation. Our analysis demonstrates that depending on the cell fate, tumor initiation vs normal development, elevated levels of CD271 can serve as a switch between proliferation/survival and differentiation/cell death. Two divergent arms of neurotrophin signaling hold the balance between positive regulators of proliferation, selfrenewal, and survival controlled by E2F, MYC, SREBP1 and AKT3 pathways on the one hand, and differentiation, senescence, and apoptosis controlled by TRAF6/IRAK-dependent activation of AP1 and TP53 mediated processes on the other hand. A molecular network map revealed in this study uncovers CD271 as a context-specific molecular switch between normal development and malignant transformation. https://doi.org/10.1038/s41598-019-42773-y http://orcid.org/0000-0001-9889-5727