Targeting the Hippo pathway in cancers via ubiquitination dependent TEAD degradation

  1. Trang H. Pham
  2. Kanika Bajaj Pahuja
  3. Thijs J. Hagenbeek
  4. Jason Zbieg
  5. Cameron L. Noland
  6. Victoria C. Pham
  7. Xiaosai Yao
  8. Christopher M. Rose
  9. Kristen C. Browder
  10. Ho-June Lee
  11. Mamie Yu
  12. May Liang-Chu
  13. Scott Martin
  14. Erik Verschueren
  15. Jason Li
  16. Marta H. Kubala
  17. Rina Fong
  18. Maria Lorenzo
  19. Paul Beroza
  20. Peter Hsu
  21. Sayantanee Paul
  22. Elisia Villemure
  23. Wendy Lee
  24. Tommy K. Cheung
  25. Saundra Clausen
  26. Jennifer Lacap
  27. Yuxin Liang
  28. Jason Cheng
  29. Steve Schmidt
  30. Zora Modrusan
  31. Michael Cohen
  32. James Crawford
  33. Heinrich Jasper
  34. Alan Ashworth
  35. Jennie R. Lill
  36. Shiva Malek
  37. Joachim Rudolph
  38. Ingrid E. Wertz
  39. Matthew T. Chang
  40. Xin Ye
  41. Anwesha Dey
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Abstract

The Hippo pathway is among the most frequently altered key signaling pathways in cancer. TEAD1-4 are essential transcription factors and key downstream effectors in the Hippo pathway in human cells. Here, we identified RNF146 as a ubiquitin ligase (E3) of TEADs, which negatively regulates their stability in cells through proteasome-mediated degradation. We show that RNF146-mediated TEAD ubiquitination is dependent on the TEAD PARylation state. We further validated the genetic interaction between RNF146 and the Hippo pathway in cancer cell lines and the model organismDrosophila melanogaster.Despite the RNF146 and proteasome-mediated degradation mechanisms, TEADs are stable proteins with a long half-life in cells. We demonstrate that degradation of TEADs can be greatly enhanced pharmacologically with heterobifunctional chemical inducers of protein degradation (CIDEs). These TEAD-CIDEs can effectively suppress activation of YAP/TAZ target genes in a dose-dependent manner and exhibit significant anti-proliferative effects in YAP/TAZ-dependent tumor cells, thus phenocopying the effect of genetic ablation of TEAD protein. Collectively, this study demonstrates that the ubiquitin-proteasome system plays an important role in regulating TEAD functions and provides a proof-of-concept demonstration that pharmacologically induced TEAD ubiquitination could be leveraged to target YAP/TAZ-driven cancers.

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