Understanding and overcoming innate and acquired MAPK-inhibition resistance in anaplastic thyroid cancer

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Abstract

Anaplastic thyroid cancer (ATC) is one of the most lethal human cancers, with some patients succumbing to the disease within weeks of diagnosis. Although a subset of patients with ATC with BRAF V600E mutation respond to the monomeric type I RAF inhibitor (RAFi) dabrafenib in combination with MEK inhibitor (MEKi) trametinib, most rapidly develop adaptive or acquired resistance. These patients, along with those who do not harbor the BRAF V600E alteration, have limited treatment options. To understand the mechanism of resistance to dabrafenib and trametinib, we utilized multi-region whole genome, high-coverage whole exome and single nuclei RNA-sequencing of ATC patient tumours to unravel genomic, transcriptomic, and microenvironmental evolution during type I RAFi and MEKi therapy. Single-cell nuclei RNA sequencing of matched primary and resistant ATC patient tumours identified reactivation of the MAPK-pathway, along with immunosuppressive macrophage proliferation, underlying the development of acquired resistance. Our translational genomics led us that hypothesize that type II RAFi, which inhibit both RAF monomers and dimers, can be efficacious in overcoming treatment resistance. Screening of a panel of type II RAFi revealed that ATC cell lines are exquisitely sensitive to the type II RAFi, naporafenib, by inhibiting EphA2-mediated MAPK-signaling. We further demonstrated that naporafenib, in combination with the MEKi trametinib, can durably and robustly overcome both innate and acquired treatment resistance to dabrafenib and trametinib using ATC cell lines and patient-derived xenograft models. Finally, we describe a novel mechanism of acquired resistance to type II RAFi and MEKi through compensatory mutations in MAST1 . Taken together, our work using translational and functional genomics has unraveled the differential mechanisms of treatment resistance to type I and type II RAFi in combination with trametinib and rationalizes the clinical investigation of type II RAFi in the setting of thyroid cancer.

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