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A unique hyperdynamic dimer interface permits small molecule perturbation of the melanoma oncoprotein MITF for melanoma therapy.

Zaizhou LiuKaige ChenJun DaiPeng XuWei SunWanlin LiuZhixin ZhaoSteven P BennettPeifeng LiTiancheng MaYuqi LinAkinori KawakamiJing YuFei WangChunxi WangMiao LiPeter ChasePeter HodderTimothy P SpicerLouis ScampaviaChunyang CaoLifeng PanJiajia DongYong ChenBiao YuMin GuoPengfei FangDavid E FisherJing Wang
Published in: Cell research (2023)
Microphthalmia transcription factor (MITF) regulates melanocyte development and is the "lineage-specific survival" oncogene of melanoma. MITF is essential for melanoma initiation, progression, and relapse and has been considered an important therapeutic target; however, direct inhibition of MITF through small molecules is considered impossible, due to the absence of a ligand-binding pocket for drug design. Here, our structural analyses show that the structure of MITF is hyperdynamic because of its out-of-register leucine zipper with a 3-residue insertion. The dynamic MITF is highly vulnerable to dimer-disrupting mutations, as we observed that MITF loss-of-function mutations in human Waardenburg syndrome type 2 A are frequently located on the dimer interface and disrupt the dimer forming ability accordingly. These observations suggest a unique opportunity to inhibit MITF with small molecules capable of disrupting the MITF dimer. From a high throughput screening against 654,650 compounds, we discovered compound TT-012, which specifically binds to dynamic MITF and destroys the latter's dimer formation and DNA-binding ability. Using chromatin immunoprecipitation assay and RNA sequencing, we showed that TT-012 inhibits the transcriptional activity of MITF in B16F10 melanoma cells. In addition, TT-012 inhibits the growth of high-MITF melanoma cells, and inhibits the tumor growth and metastasis with tolerable toxicity to liver and immune cells in animal models. Together, this study demonstrates a unique hyperdynamic dimer interface in melanoma oncoprotein MITF, and reveals a novel approach to therapeutically suppress MITF activity.
Keyphrases
  • transcription factor
  • small molecule
  • dna binding
  • gene expression
  • endothelial cells
  • emergency department
  • dna methylation
  • oxidative stress
  • skin cancer
  • dna damage
  • protein protein