eIF2B Selectively Anchors and Activates Mutant KRAS

  1. Hyungdong Kim
  2. Shiqi Diao
  3. Kwang-Jin Cho
  4. Hyun-Ro Lee
  5. Junchen Liu
  6. Pascal Egea
  7. Tatu Pantsar
  8. Milla Kurki
  9. Nour Ghaddar
  10. Shuo Wang
  11. Jia Yi Zou
  12. Mehdi Amiri
  13. Ritchel Gannaban
  14. John Hancock
  15. Kylie M. Rice
  16. Qiyun Deng
  17. Atsuo Sasaki
  18. John Asara
  19. Brajendra Tripathi
  20. Douglas Lowy
  21. Rosalie Lawrence
  22. Maria Hatzoglou
  23. Carlos R Azpilcueta-Nicolas
  24. Jean-Philip Lumb
  25. John Columbus
  26. Thomas J Turbyville
  27. Christopher B. Marshall
  28. Mitsuhiko Ikura
  29. Jay T. Groves
  30. Nahum Sonenberg
  31. Peter Walter
  32. Antonis E. Koromilas
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Abstract

Much is known about how RAS oncoproteins regulate mRNA translation factors, but the reverse relationship, how translation factors influence RAS activity, has remained largely unexplored. At the plasma membrane (PM), Son of Sevenless (SOS) acts as the canonical guanine nucleotide exchange factor (GEF) for RAS proteins, yet mechanisms governing its specificity for individual RAS isoforms remain unknown. Here, we show that the translation initiation factor eIF2B, best known for its GEF function in translation initiation, forms a distinct complex with SOS and mutant KRAS at the PM, but not with other oncogenic RAS variants. Mechanistically, eIF2B acts as an allosteric regulator of SOS, selectively enhancing GDP–GTP exchange on mutant KRAS. This specificity arises from the translational activity of eIF2B, which upregulates glycosphingolipid (GSL) biosynthesis to remodel PM lipids and preferentially anchor mutant KRAS. Together, our results uncover an unexpected moonlighting function of eIF2B: acting both as a direct activator of SOS and as a regulator of GSL pathway that shapes the membrane landscape, both required for mutant KRAS activation. These insights redefine our understanding of eIF2B and mutant KRAS functions in cancer and have profound implications for KRAS-driven oncogenesis.

Graphical Abstract

  • eIF2B interacts with mutant KRAS and SOS at the plasma membrane (PM).

  • The eIF2B:SOS complex promotes the GTP-bound active state of mutant KRAS.

  • eIF2B enhances the translation of B4GALT5 mRNA, encoding a key enzyme of glycosphingolipid (GSL) biosynthesis.

  • Upregulation of the GSL metabolites, ganglioside GM3 and sulfatide SM4, remodels PM lipid composition to facilitate eIF2B:SOS:KRAS complex formation and mutant KRAS nanoclustering.

  • Through its interaction with SOS and stimulation of GSL synthesis, eIF2B selectively activates mutant KRAS at the PM among RAS isoforms.

  • eIF2B is required for the development of mKRAS-driven lung adenocarcinoma in mice.

  • eIF2B is a marker of poor prognosis in mutant KRAS-driven cancers.

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  1. Version published to 10.1101/2025.11.10.686860 on bioRxiv