DNA promoter hypermethylation of melanocyte lineage genes determines melanoma phenotype
Adriana Sanna, … , Kristian Pietras, Göran Jönsson
Adriana Sanna, … , Kristian Pietras, Göran Jönsson
Published August 30, 2022
Citation Information: JCI Insight. 2022;7(19):e156577. https://doi.org/10.1172/jci.insight.156577.
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Research Article Cell biology Oncology

DNA promoter hypermethylation of melanocyte lineage genes determines melanoma phenotype

Abstract

Cellular stress contributes to the capacity of melanoma cells to undergo phenotype switching into highly migratory and drug-tolerant dedifferentiated states. Such dedifferentiated melanoma cell states are marked by loss of melanocyte-specific gene expression and increase of mesenchymal markers. Two crucial transcription factors, microphthalmia-associated transcription factor (MITF) and SRY-box transcription factor 10 (SOX10), important in melanoma development and progression, have been implicated in this process. In this study we describe that loss of MITF is associated with a distinct transcriptional program, MITF promoter hypermethylation, and poor patient survival in metastatic melanoma. From a comprehensive collection of melanoma cell lines, we observed that MITF-methylated cultures were subdivided in 2 distinct subtypes. Examining mRNA levels of neural crest–associated genes, we found that 1 subtype had lost the expression of several lineage genes, including SOX10. Intriguingly, SOX10 loss was associated with SOX10 gene promoter hypermethylation and distinct phenotypic and metastatic properties. Depletion of SOX10 in MITF-methylated melanoma cells using CRISPR/Cas9 supported these findings. In conclusion, this study describes the significance of melanoma state and the underlying functional properties explaining the aggressiveness of such states.

Authors

Adriana Sanna, Bengt Phung, Shamik Mitra, Martin Lauss, Jiyeon Choi, Tongwu Zhang, Ching-Ni Njauw, Eugenia Cordero, Katja Harbst, Frida Rosengren, Rita Cabrita, Iva Johansson, Karolin Isaksson, Christian Ingvar, Ana Carneiro, Kevin Brown, Hensin Tsao, My Andersson, Kristian Pietras, Göran Jönsson

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Figure 6

CRISPR/Cas9 editing of SOX10 in MITF-methylated melanomas.

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CRISPR/Cas9 editing of SOX10 in MITF-methylated melanomas. (A) Target se...
(A) Target sequence and confirmation of SOX10 KO by Sanger sequencing and Western blot in MM383 melanoma cells. (B) Transcriptomic analysis describes differences in the expression levels of NC-associated genes between SOX10WT (black) and SOX10KO (clone 1, green) cells. * indicates significantly different expression (FDR = 0). (C) Migration of SOX10WT (black) and SOX10KO (green) cells analyzed using a Transwell assay shows decreased migratory potential of the SOX10KO clones. P value was calculated using Mann-Whitney-Wilcoxon test. (D) Treatment of SOX10WT (black) and SOX10KO (green) cells with BRAF inhibitors shows increased resistance of the SOX10KO clones compared with wild-type cells. P value was calculated using 1-way ANOVA with Dunnett’s multiple-comparison test. (E) β-Galactosidase staining used to measure the fraction of senescent cells in SOX10WT (black) and SOX10KO (green) displays higher senescent cell count in the SOX10KO clones. P value was calculated using Mann-Whitney-Wilcoxon test. Original magnification, ×400. (F) Box plot showing difference in weight between SOX10WT (black) and SOX10KO (green) derived primary tumors and tumor photos. P value were calculated using Mann-Whitney-Wilcoxon test. (G) qPCR analysis of human GAPDH in brain tissues from SOX10WT (black) and SOX10KO (green) melanoma-injected NSG mice. Representative immunostaining of SOX10KO mouse brain tissue using human nuclear mitochondria antibody. P value was calculated using Mann-Whitney-Wilcoxon test.