Differential histone acetylation and super-enhancer regulation underlie melanoma cell dedifferentiation

Karen Mendelson, Tiphaine C. Martin, Christie B. Nguyen, Min Hsu, Jia Xu, Claudia Lang, Reinhard Dummer, Yvonne Saenger, Jane L. Messina, Vernon K. Sondak, Garrett Desman, Dan Hasson, Emily Bernstein, Ramon E. Parsons, Julide Tok Celebi

Research output: Contribution to journalArticlepeer-review


Dedifferentiation or phenotype switching refers to the transition from a proliferative to an invasive cellular state. We previously identified a 122-gene epigenetic gene signature that classifies primary melanomas as low versus high risk (denoted as Epgn1 or Epgn3). We found that the transcriptomes of the Epgn1 low-risk and Epgn3 high-risk cells are similar to the proliferative and invasive cellular states, respectively. These signatures were further validated in melanoma tumor samples. Examination of the chromatin landscape revealed differential H3K27 acetylation in the Epgn1 low-risk versus Epgn3 high-risk cell lines that corroborated with a differential super-enhancer and enhancer landscape. Melanocytic lineage genes (MITF, its targets and regulators) were associated with super-enhancers in the Epgn1 low-risk state, whereas invasiveness genes were linked with Epgn3 high-risk status. We identified the ITGA3 gene as marked by a super-enhancer element in the Epgn3 invasive cells. Silencing of ITGA3 enhanced invasiveness in both in vitro and in vivo systems, suggesting it as a negative regulator of invasion. In conclusion, we define chromatin landscape changes associated with Epgn1/Epgn3 and phenotype switching during early steps of melanoma progression that regulate transcriptional reprogramming. This super-enhancer and enhancer-driven epigenetic regulatory mechanism resulting in major changes in the transcriptome could be important in future therapeutic targeting efforts.

Original languageEnglish
Article numbere166611
JournalJCI insight
Issue number6
StatePublished - 26 Feb 2024


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