Project description:We analyzed, by HTA 2.0, the GBM cell lines LN-18, LN-229, and U-87 MG after fluoresence-activated cell sorting (FACS) into ABCB5+ and ABCB5- fractions. Poor prognosis associated with glioblastoma multiforme (GBM) results from tumor resistance to therapy and high rate of recurrence. Compelling evidence suggests this is driven by subpopulations of slow-proliferating cancer stem cells with tumor-initiating potential. ATP-binding cassette member B5 (ABCB5) has been identified as a molecular marker for distinct subsets of chemoresistant tumor-initiating cell populations in diverse human malignancies. In the current study, we examined the potential role of ABCB5 in growth and chemoresistance of GBM. We found ABCB5 to be preferentially expressed in clinical GBM tumors and co-expressed with the stem cell marker CD133 in subpopulations of human GBM cell lines U-87 MG, LN-18 and LN-229. Antibody-mediated functional ABCB5 blockade inhibited proliferation and survival of human GBM cells and sensitized them to temozolomide (TMZ)-induced apoptosis. Likewise, in an in vivo GBM xenograft study in immunodeficient mice, anti-ABCB5 monoclonal antibody treatment inhibited tumor growth and sensitized tumors to TMZ therapy. Mechanistically, we demonstrated that ABCB5 regulates cell cycle checkpoint molecules to revoke drug-induced G2-M arrest and augments drug-mediated cell death. Overall, our data establish ABCB5 as a marker of GBM chemoresistance and point to the potential of ABCB5 targeting in improvement of current GBM therapies.

Project description:Circulating Tumour Cells (CTCs) act as tumour seeds for haematogeneous melanoma spread of melanoma. Since CTCs have been reported to be heterogeneous in melanoma, the characterisation of the different melanoma CTC subpopulations harbours biological and clinical significance. For detection of melanoma CTCs, melanoma-associated markers (i.e. MCSP, melanoma-associated chondroitin sulphate proteoglycan) have been used; however, recent studies have found that melanoma CTCs commonly express ABCB5 (ATP-binding cassette sub-family B member 5) a melanoma-initiating marker. Here, we used a genome-wide expression microarray to interrogate the transcriptome of MCSP-enriched and ABCB5-enriched CTC fraction in order to provide a better understanding of their biology and role in melanoma metastasis. Findings from this study highlited the distinct transcriptional programming of both CTC subpopulations.

Project description:Functional analysis of ABCB5 in A375 and G3361 melanoma cells, by comparing stably-transfected controls to ABCB5-shRNA-targeted cells. 12 samples total. Replicates n=3 for the following 4 groups: A375 pSUPER-retro-puro-Vector vs. A375 pSUPER-retro-puro-ABCB5-KD; G3361 pSUPER-retro-puro-shCNTRL vs. G3361 pSUPER-retro-puro-ABCB5-KD.

Project description:Functional analysis of ABCB5 in A375 and G3361 melanoma cells, by comparing stably-transfected controls to ABCB5-shRNA-targeted cells.

Project description:ABCB5 is marker for Limbal epithilal stem cells. A comparison between ABCB5+ versus ABCB5- cultured human limbal epithelial cells was carried out to evaluate the properties of the limbal stem cell ABCB5+ with a special focus on their role in inflammation and angiogenesis.

Project description:The goal of this study was to unlock the cellular diversity of A2058, a melanoma cell line known to be resistant to BRAF inhibition, by performing single cell RNAseq profiling using a 10X genomics platform. This approach allowed us to study the transcriptional programming of every single melanoma cell, particularly of those cells expressing ABCB5, a cell surface protein involved in invasiveness and resistance to BRAF inhibition. Findings from this study revelaed that ABCB5-expressing cells also expressed melanocytic genes (MITF) but with a distinct transcriptional program to those expressing AXL. We also used this data to identify the expresion of commonly studied drug efflux pumps in melanoma cells.

Project description:Expression data from ABCB5-positive and ABCB5-negative GBM cells

Project description:Melanoma growth is driven by malignant melanoma initiating cells (MMIC) identified by expression of the ATP-binding cassette (ABC) member, ABCB5. ABCB5+ melanoma subpopulations have been shown to overexpress the vasculogenic differentiation markers CD144 (VE-cadherin) and TIE-1 and are associated with CD31-negative vasculogenic mimicry (VM), an established biomarker associated with increased patient mortality. Here we identify a critical role for VEGFR-1 signaling in ABCB5+ MMIC-dependent VM and tumor growth. Global gene expression analyses, validated by mRNA and protein determinations, revealed preferential expression of VEGFR-1 on ABCB5+ tumor cells purified from clinical melanomas and established melanoma lines. In vitro, VEGF induced in a VEGFR-1-dependent manner expression of CD144 in ABCB5+ subpopulations that constitutively expressed VEGFR-1, but not in ABCB5- bulk populations that were predominantly VEGFR-1-negative. In vivo, melanomaspecific shRNA-mediated knockdown of VEGFR-1 blocked the development of ABCB5+ VM morphology and inhibited ABCB5+ VM-associated production of the secreted melanoma mitogen, laminin. Moreover, melanoma-specific VEGFR-1 knockdown markedly inhibited tumor growth (by >90%). Our results demonstrate that VEGFR-1 function in MMIC regulates VM and associated laminin production, and show that this function represents one mechanism through which MMIC promote tumor growth. Microarray analyses were performed on purified ABCB5+ (n=5) and ABCB5- (n=5) cell subsets derived from the established human melanoma cell lines G3361 and A375 and from three distinct clinical melanoma specimen. Total RNA was extracted, processed and hybridized onto Affymetrix human HG-U133Plus2 GeneChip microarrays (Affymetrix, Santa Clara, CA).

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:ABCB5 is activated by MITF and b-catenin and is associated with melanoma differentiation