Abstract
8542 Background: The acquisition of new mutations can explain resistance to targeted therapies; however resistance also develops without demonstrable new mutations. To better understand potential mechanisms for treatment failure we studied subpopulations of chemo-resistant cells that can be identified in early passage cell lines and the cellular plasticity that yields these. Methods: Melanoma subpopulations were identified and sorted on the basis of functional assays. Gene expression was evaluated with Illumina HT12 arrays and qPCR to identify potential mechanisms and targets. Sorted cells were evaluated in vitro for the induction of phenotype switching and effects of target inhibition. Results: A subset of slow proliferating label-retaining cells (LRC) was identified using a membrane dye. Direct isolation of LRC from a pt showed these were not an in vitro artefact. LRC isolated from multiple cell lines comprised the majority of cells that resisted cytotoxic drugs and could invade through an artificial extracellular membrane. Gene expression profiling identified a network of over-expressed genes related to epithelial-to-mesenchymal transition (EMT) notable for the expression of Thrombospondin-1 (TSP-1), Transforming-Growth Factor, Beta Induced, (TGFBI) and other extracellular matrix molecules. Initial studies show that LRC shared gene expression characteristics with PLX4032-resistant cells. Although interrogating LRC by qPCR showed up-regulation of the putative melanoma stem cell marker ABCB5 and the lysine specific demethylase Jarid1B, cell sorting and serial re-labelling experiments revealed a dynamic and interchangeable phenotype for these cells, challenging the hierarchical stem cell model for melanoma. The observed slow-cycling and chemo-resistant phenotype could be induced in vitro through TGF beta-mediated phenotype switching and cellular invasion was blocked using an antibody against TSP-1. Conclusions: Cytokine-induced plasticity in melanoma yields invasive, therapy-resistant cells which express EMT-related genes and pathways. We hypothesize that these cells are a source of treatment resistance in vivo and blocking their emergence may prevent treatment failure.
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