Myosin II Reactivation and Cytoskeletal Remodeling as a Hallmark and a Vulnerability in Melanoma Therapy Resistance

José L. Orgaz(Queen Mary University of London), Eva Crosas‐Molist(Queen Mary University of London), Amine Sadok(Institute of Cancer Research), Anna Perdrix-Rosell(Queen Mary University of London), Óscar Maiques(Queen Mary University of London), Irene Rodríguez‐Hernández(Queen Mary University of London), Jo Monger(Queen Mary University of London), Silvia Mele(St Thomas' Hospital), Mirella Georgouli(King's College London), Victoria L. Bridgeman(The Francis Crick Institute), Panagiotis Karagiannis(St Thomas' Hospital), Rebecca Lee(Cancer Research UK Manchester Institute), Pahini Pandya(King's College London), Lena Boehme(King's College London), Fredrik Wållberg(Institute of Cancer Research), Christopher J. Tape(CRUK Lung Cancer Centre of Excellence), Sophia N. Karagiannis(St Thomas' Hospital), Ilaria Malanchi(The Francis Crick Institute), Victoria Sanz‐Moreno(Queen Mary University of London)
Cancer Cell
January 1, 2020
10.1016/j.ccell.2019.12.003
Cited by 150Open Access
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Abstract

Despite substantial clinical benefit of targeted and immune checkpoint blockade-based therapies in melanoma, resistance inevitably develops. We show cytoskeletal remodeling and changes in expression and activity of ROCK-myosin II pathway during acquisition of resistance to MAPK inhibitors. MAPK regulates myosin II activity, but after initial therapy response, drug-resistant clones restore myosin II activity to increase survival. High ROCK-myosin II activity correlates with aggressiveness, identifying targeted therapy- and immunotherapy-resistant melanomas. Survival of resistant cells is myosin II dependent, regardless of the therapy. ROCK-myosin II ablation specifically kills resistant cells via intrinsic lethal reactive oxygen species and unresolved DNA damage and limits extrinsic myeloid and lymphoid immunosuppression. Efficacy of targeted therapies and immunotherapies can be improved by combination with ROCK inhibitors.

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