A novel hypoxia-associated subset of FN1 high MITF low melanoma cells: identification, characterization, and prognostic value.

In many human cancers, the epithelial-to-mesenchymal transition has an important role in the induction of cancer stem-like cells, and hence, in the causation of intratumoral heterogeneity. This process, also referred to as mesenchymal mimicry, is, however, only poorly understood in melanoma and histological correlation is still lacking. In an immunohistochemical analysis of a large prospective series of 220 primary and metastatic melanomas for the well-known epithelial-to-mesenchymal transition marker FN1, we observed melanoma cells with high FN1 expression in metastases with ischemic necrosis, but rarely or not at all in samples lacking evidence of hypoxia. In a blinded, retrospective series of 82 melanoma metastases with 10-year follow-up, the presence of clusters of these FN1(high) melanoma cells correlated significantly with shortened melanoma-specific survival, highlighting the prognostic value of their presence. We describe in detail the unique light- and electron-microscopic features of these FN1(high) melanoma cells, enabling their identification in routinely hematoxylin-and-eosin-stained sections. In addition, by laser microdissection and subsequent gene expression analysis and immunohistochemistry, we highlight their distinctive, molecular phenotype that includes expression of various markers of the epithelial-to-mesenchymal transition (eg, ZEB1) and of melanoma stem-like cells (eg, NGFR), and lack of immunoreactivity for the melanocytic marker MITF. This phenotype could be reproduced in vitro by culturing melanoma cells under hypoxic conditions. Functionally, the hypoxic microenvironment was shown to induce a more migratory and invasive cell type. In conclusion, we identified a novel clinically relevant FN1(high)MITF(low) cell type in melanoma associated with ischemic necrosis, and propose that these cells reside at the crossroad of the epithelial-to-mesenchymal transition and stem-like cell induction, plausibly triggered by the hypoxic environment.

Pattern of sensitivity of progressive cutaneous squamous cell carcinoma cells to UVB and oxidative stress-induced cell death.

Previous investigations have demonstrated that isogenic cutaneous squamous cell carcinoma cell lines (cSCC), isolated from highly dysplastic skin (PM1), primary invasive SCC (MET1) and its lymph node metastasis (MET4), show an increasing resistance to cisplatin-induced apoptosis in the increasingly malignant MET1 and MET4 cells. To investigate whether cell death sensitivity in progressive stages of skin carcinogenesis is dependent on the kind of stress we examined the sensitivity of PM1, MET1 and MET4 cells to apoptosis in response to a single UVB-dose (mixture of genotoxic and oxidative stress), or to hydrogen peroxide and hypericin photodynamic treatment (both pure oxidative stresses). MET1 cells, followed by the MET4 cells, were more sensitive to UVB, resulting in more cell death and more apoptosis in comparison with the PM1 cells. A similar pattern of sensitivity was observed when we exposed the SCC cells to hydrogen peroxide or hypericin photodynamic treatment, which both generate mainly oxidative stress. The MET1 cells were the most sensitive to all stresses examined. The pattern of cell death sensitivity in a model of progressive cutaneous squamous cell carcinoma is dependent on the kind of stress. While more advanced skin cancer cells like MET1 and MET4 cells lose their sensitivity to the chemotherapeutic agent cisplatin, they remain sensitive to hydrogen peroxide or physical treatments, which induce major oxidative stress. This differential sensitivity could have implications for the treatment of advanced cSCC.

Autophagy inhibitor chloroquine enhanced the cell death inducing effect of the flavonoid luteolin in metastatic squamous cell carcinoma cells.

BACKGROUND: Flavonoids are widely proposed as very interesting compounds with possible chemopreventive and therapeutic capacities. METHODS & RESULTS: In this study, we showed that in vitro treatment with the flavonoid Luteolin induced caspase-dependent cell death in a model of human cutaneous squamous cell carcinoma (SCC) derived cells, representing a matched pair of primary tumor and its metastasis. Notably, no cytotoxic effects were observed in normal human keratinocytes when treated with similar doses of Luteolin. Luteolin-induced apoptosis was accompanied by inhibition of AKT signaling, and sensitivity decreased with tumor progression, as the primary MET1 SCC cells were considerably more sensitive to Luteolin than the isogenic metastatic MET4 cells. Extensive intracellular vacuolization was observed in Luteolin-treated MET4 cells, which were characterized as acidic lysosomal vacuoles, suggesting the involvement of autophagy. Transmission electron microscopy, mRFP-GFP-LC3 assay and p62 protein degradation, confirmed that Luteolin stimulated the autophagic process in the metastatic MET4 cells. Blocking autophagy using chloroquine magnified Luteolin-induced apoptosis in the metastatic SCC cells. CONCLUSION: Together, these results suggest that Luteolin has the capacity to induce selectively apoptotic cell death both in primary cutaneous SCC cells and in metastatic SCC cells in combination with chloroquine, an inhibitor of autophagosomal degradation. Hence, Luteolin might be a promising agent for the treatment of cutaneous SCC.