Abstract
Abstract The discovery of BRAF mutations in around 60% of melanoma patients and the subsequent development of targeted inhibitors to counter the hyperactive BRAF-driven pro-tumorigenic signaling pathway have marked a significant milestone in melanoma therapy. However, despite this progress, the long-term outcomes remain unsatisfactory for many patients due to the occurrence of drug resistance. We previously reported that cancer-associated fibroblasts (CAFs) are stimulated by BRAF inhibitors (BRAFi) to drive matrix remodeling and therapeutic escape pathways in melanoma cells. However, the underlying mechanism by which CAFs are reprogrammed by BRAFi to obtain enhanced phenotypes remains elusive. Here, we present compelling evidence showing that BRAFi (PLX4032), but not CRAF inhibitor (GW5074) or pan-RAF inhibitor (RAF709), induces the accumulation of nuclear β-catenin in CAFs harboring wild-type BRAF, a process mediated by BRAF and CRAF but not ARAF isoform. BRAFi binding to BRAF and CRAF leads to robust RAF kinase dimerization, including BRAF and CRAF homodimer and BRAF: CRAF heterodimer. RAF dimers are subsequently recruited to the plasma membrane, where BRAF and CRAF are phosphorylated on residues Thr599 and Ser338, respectively, and activated in a RAS-GTP-dependent manner. RAF activation stimulates the downstream Rho kinase (ROCK) and MEK/ERK signaling pathways simultaneously. Notably, ablating RAS and RAF isoforms effectively suppressed BRAFi-induced activation of ROCK1/2 signaling in CAFs, further confirming that the ROCK pathway is a downstream effector of BRAFi-driven RAF activation and is intricately linked to increased nuclear β-catenin in CAFs. The pharmacological blockade of ROCK activity, using HA-1077, diminished BRAFi-induced nuclear β-catenin accumulation in CAFs, suggesting BRAFi-driven cytoskeletal remodeling plays a pivotal role in the nuclear shuttling of β-catenin. Using a mouse model that mimics human BRAF-mutant melanoma, we found that elevated level of nuclear β-catenin drives the conversion of fibroblasts into α-SMA-positive CAFs, leading to elevated collagen deposition and contributing to melanoma progression in vivo. In summary, BRAFi reprograms the transcriptional activity in CAFs by driving increased nuclear β-catenin to increase their ability to remodel the tumor ECM and promote melanoma cell proliferation. Collectively, the data offer new insights into the molecular mechanisms that underlie the paradoxical reprogramming of CAFs by BRAFi in melanoma therapy through the non-canonical β-catenin pathway. Citation Format: Bruna da Silva Soley, Radhika Athalye, Ryan Zhang, Thomas Andl, Yuhang Zhang. BRAFi-induced ROCK-mediated non-canonical nuclear β-catenin shuttling drives a phenotypic switch in cancer-associated fibroblasts [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 296.
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