Comparative gene expression profiling of parental A375 melanoma cells and a panel of spontaneously vemurafenib-resistant derivative cell lines

The use of selective BRAF inhibitors (BRAFi) has produced remarkable outcomes for patients with advanced cutaneous melanoma harboring a BRAFV600E mutation. Unfortunately, the majority of patients eventually develop drug-resistant disease through a variety of mechanisms. We previously described the creation of a panel of spontaneously BRAFi/MEKi-resistant A375 melanoma cells that displayed multiple different resistance mechanisms arising within the same parental cell population. These resistance mechanisms include (i) rearrangements in the BRAF gene resulting in truncation of the N-terminal regulatory domain or tandem duplication of the BRAF kinase domain, (ii) loss of Ras-GAP NF1, and (iii) a slower arising form of drug resistance associated with a more spread cell morphology and increased phospho-MEK S298, a characteristic of cells with increased Rac1 signaling. We provide here comprehensive gene expression profiling for this panel of cell lines. Rac1 mutation, particularly the P29S variant, is common in melanoma patients, where it is associated with BRAFi/MEKi resistance and worse clinical outcomes. Here we delineate mechanisms of Rac1-driven MAPKi-resistance and identify strategies to inhibit the growth of this class of cutaneous melanomas. We find that Rac1-driven melanomas manifest pleiotropic resistance mechanisms including (i) reduced dependence on BRAF/MEK, (ii) activation of alternative MAPK pathways utilizing Jun kinase and p38 MAP kinase, and (iii) a partial reliance on YAP/TAZ signaling. Importantly, although Rac1-driven melanoma cells display reduced dependence on BRAF/MEK, they are not completely ERK-independent. Moreover, the presence of activated Rac1 appears to create a dependency on focal adhesion kinase (FAK) signaling in undifferentiated melanoma cells. As a result, we find that, despite the pleiotropic mechanisms of Rac1-driven MAPKi resistance, combined inhibition of MEK and FAK with avutometinib plus defactinib is a promising approach for suppressing the growth of Rac1-driven cells. Thus, the avutometinib plus defactinib combination, which is currently being investigated for brain metastatic cutaneous melanoma may also have utility against Rac1-driven MAPKi-resistance in heavily pre-treated, advanced disease. RNAseq profiling of parental A375 cells, A735 cells treated with vemurafenib for 24 or 96 hours, and a panel of 8 spontaneously vemurafenib-resistant A375 derivative cell lines