Interface of post-translational glycosylation and ER stress in melanoma: target to cancer cell sensitization to chemotherapeutic agents?

Melanoma is the most lethal skin cancer, despite being the least prevalent. Due to its lethality and resistance to a variety of known chemotherapeutic drugs, studies on melanoma are paramount. Tumor cells in general, and melanoma cells particularly, commonly present a disturbed metabolic rate, e.g., altered metabolism of reactive oxygen species and increased rates of protein synthesis. Altogether these perturbations trigger the Unfolded Protein Response (UPR); however, tumor cells are adapted to these conditions and are able to survive. Besides, glycosylation of tumor cells is commonly altered, due to differentiated expression rates of N-glycosylation enzymes, like N-acetylglucosaminyltransferase 5 (MGAT5). Considering these information together, we proposed that the sustained overexpression of MGAT5A (and/or MGAT5B) observed in Tm1 and Tm5 melanoma cells is part of an adaptive response to reticulum stress, maintaining an unstable equilibrium in tumor cells. In this work, we observed that the induction of endoplasmic reticulum stress caused by tunicamycin treatment, a N-glycosylation inhibitor and UPR inducer, sensitized melanoma cells to further cisplatin treatment. In contrast, swainsonine treatment, an inhibitor of Golgi N-glycan processing pathway, did not cause cell death nor UPR signaling, and this may be the reason why this treatment did not sensitize cells to cisplatin treatment. MGAT5A silencing was not successful yet. Altogether, the results above show that the unstable equilibrium under which Tm1 and Tm5 tumor cells are seems necessary for their survival. Therefore, it seems that upon malignant transformation, melanoma cells present dependence of MGAT5A expression. Its our interest exploit this melanoma model to understand the concept of oncogenic dependence for MGAT5A expression in the case of melanomas, if it exists (AU)