A distinct pattern of growth and RAC1 signaling in melanoma brain metastasis cells

Abstract Background Melanoma, the deadliest of skin cancers, has a high propensity to form brain metastases that are associated with a markedly worsened prognosis. In spite of recent therapeutic advances, melanoma brain lesions remain a clinical challenge, biomarkers predicting brain dissemination a...

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Published in:Neuro-oncology (Charlottesville, Va.) Va.), 2023-04, Vol.25 (4), p.674-686
Main Authors: Stejerean-Todoran, Ioana, Gimotty, Phyllis A, Watters, Andrea, Brafford, Patricia, Krepler, Clemens, Godok, Tetiana, Li, Haiyin, Bonilla del Rio, Zuriñe, Zieseniss, Anke, Katschinski, Dörthe M, Sertel, Sinem M, Rizzoli, Silvio O, Garman, Bradley, Nathanson, Katherine L, Xu, Xiaowei, Chen, Qing, Oswald, Jack H, Lotem, Michal, Mills, Gordon B, Davies, Michael A, Schön, Michael P, Bogeski, Ivan, Herlyn, Meenhard, Vultur, Adina
Format: Article
Language:English
Subjects:
Basic and Translational Investigations
Biomarkers
Brain Neoplasms - genetics
Humans
Melanoma - pathology
Prognosis
rac1 GTP-Binding Protein - metabolism
Skin Neoplasms
Tumor Microenvironment
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Summary:Abstract Background Melanoma, the deadliest of skin cancers, has a high propensity to form brain metastases that are associated with a markedly worsened prognosis. In spite of recent therapeutic advances, melanoma brain lesions remain a clinical challenge, biomarkers predicting brain dissemination are not clear and differences with other metastatic sites are poorly understood. Methods We examined a genetically diverse panel of human-derived melanoma brain metastasis (MBM) and extracranial cell lines using targeted sequencing, a Reverse Phase Protein Array, protein expression analyses, and functional studies in vitro and in vivo. Results Brain-specific genetic alterations were not detected; however, MBM cells in vitro displayed lower proliferation rates and MBM-specific protein expression patterns associated with proliferation, DNA damage, adhesion, and migration. MBM lines displayed higher levels of RAC1 expression, involving a distinct RAC1-PAK1-JNK1 signaling network. RAC1 knockdown or treatment with small molecule inhibitors contributed to a less aggressive MBM phenotype in vitro, while RAC1 knockdown in vivo led to reduced tumor volumes and delayed tumor appearance. Proliferation, adhesion, and migration were higher in MBM vs nonMBM lines in the presence of insulin or brain-derived factors and were affected by RAC1 levels. Conclusions Our findings indicate that despite their genetic variability, MBM engage specific molecular processes such as RAC1 signaling to adapt to the brain microenvironment and this can be used for the molecular characterization and treatment of brain metastases. Graphical Abstract Graphical Abstract
ISSN:1522-8517
1523-5866
DOI:10.1093/neuonc/noac212