SOX2 utilizes FOXA1 as a heteromeric transcriptional partner to drive proliferation in therapy-resistant prostate cancer

  1. John T. Phoenix
  2. Audris Budreika
  3. Devin A. Schmeck
  4. Raymond J. Kostlan
  5. Marina G. Ferrari
  6. Kristen S. Young
  7. Charles S. Rogers
  8. Carleen D. Deegan
  9. Marcus W. Bienko
  10. Hannah E. Bergom
  11. Ella Boytim
  12. Ryan M. Brown
  13. Julia A. Walewicz
  14. Shreya K. Bhagi
  15. Leigh Ellis
  16. Emmanuel S. Antonarakis
  17. Justin M. Drake
  18. Pushpinder S. Bawa
  19. Jordan E. Vellky
  20. Anthony Williams
  21. Natalie M. Rezine
  22. Jonathan P. Rennhack
  23. Sean W. Fanning
  24. Justin H. Hwang
  25. Russell Z. Szmulewitz
  26. Donald J. Vander Griend
  27. Steven Kregel
Read the full article See related articles

Listed in

This article is not in any list yet, why not save it to one of your lists.
Log in to save this article

Abstract

Treatment options and diagnostic outlook for men with advanced, therapy resistant prostate cancer (PCa) are extremely poor; this is primarily due to the common lack of durable response to androgen receptor (AR) targeted therapies and phenotypic transdifferentiation into a particularly lethal subtype known as neuroendocrine prostate cancer (NEPC). In this study, we mechanistically determine that SOX2 (a transcription factor originally repressed by AR) physically binds and acts in a concerted manner with FOXA1 (a key AR pioneering cofactor) to regulate a subset of genes which promote cell cycle progression, and lineage plasticity in AR-refractory prostate cancers. Our findings assert the SOX2/FOXA1 interaction as an important mediator of resistance to AR-targeted therapy and a driver of NEPC and lineage plasticity; their coordinated action and downstream signaling offers a potential novel therapeutic opportunity in late-stage PCa.

Article activity feed

  1. Version published to 10.1101/2025.07.18.664790 on bioRxiv