Abstract
Most genetic alterations that drive melanoma development and resistance to targeted therapy have been uncovered. In contrast, and despite their increasingly recognized contribution, little is known about the non‐genetic mechanisms that drive these processes. Here, we performed in vivo gain‐of‐function CRISPR screens and identified SMAD3, BIRC3, and SLC9A5 as key actors of BRAFi resistance. We show that their expression levels increase during acquisition of BRAFi resistance and remain high in persister cells and during relapse. The upregulation of the SMAD3 transcriptional activity (SMAD3‐signature) promotes a mesenchymal‐like phenotype and BRAFi resistance by acting as an upstream transcriptional regulator of potent BRAFi‐resistance genes such as EGFR and AXL. This SMAD3‐signature predicts resistance to both current melanoma therapies in different cohorts. Critically, chemical inhibition of SMAD3 may constitute amenable target for melanoma since it efficiently abrogates persister cells survival. Interestingly, decrease of SMAD3 activity can also be reached by inhibiting the Aryl hydrocarbon Receptor (AhR), another druggable transcription factor governing SMAD3 expression level. Our work highlights novel drug vulnerabilities that can be exploited to develop long‐lasting antimelanoma therapies.
Highlights
Most genetic alterations that drive melanoma development and resistance to targeted therapy have been uncovered
To reinforce the role of SMAD3 in BRAF inhibitors (BRAFi) resistance, we showed that gain-of-function of SMAD3 significantly increases the BRAFi resistance of melanoma cells when compared to different control cells
We showed that SMAD3 inhibitor alone or in combination with BRAFi (Vem 5 μM) or BRAFi + MEKi (Cobi 1 μM) might be a promising treatment to reduce the amount of persister cells
Summary
Most genetic alterations that drive melanoma development and resistance to targeted therapy have been uncovered. We performed in vivo gain-of-function CRISPR screens and identified SMAD3, BIRC3, and SLC9A5 as key actors of BRAFi resistance. We show that their expression levels increase during acquisition of BRAFi resistance and remain high in persister cells and during relapse. The upregulation of the SMAD3 transcriptional activity (SMAD3-signature) promotes a mesenchymal-like phenotype and BRAFi resistance by acting as an upstream transcriptional regulator of potent BRAFi-resistance genes such as EGFR and AXL. This SMAD3-signature predicts resistance to both current melanoma therapies in different cohorts. Our work highlights novel drug vulnerabilities that can be exploited to develop long-lasting antimelanoma therapies
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