Reprogramming Factors Activate a Non-Canonical Oxidative Resilience Pathway That Can Rejuvenate RPEs and Restore Vision

  1. Yuancheng Ryan Lu
  2. James C. Cameron
  3. Yan Hu
  4. Han Shen
  5. Shintaro Shirahama
  6. Alexander Tyshkovskiy
  7. Zhaoyi Chen
  8. Jiahe Ai
  9. Daniel Y. Zhu
  10. Margarete M. Karg
  11. Lindsey A. Chew
  12. George W. Bell
  13. Siddhartha G. Jena
  14. Yue He
  15. Philip Seifert
  16. Daisy Y. Shu
  17. Mohamed A. EI-Brolosy
  18. Qiannuo Lou
  19. Bohan Zhang
  20. Anna M. Puszynska
  21. Xiaojie Qiu
  22. Xiao Tian
  23. Meredith Gregory-Ksander
  24. Vadim N. Gladyshev
  25. David A. Sinclair
  26. Magali Saint-Geniez
  27. Jason D. Buenrostro
  28. Catherine Bowes Rickman
  29. Bruce R. Ksander
  30. Jonathan S. Weissman
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Abstract

Oct4, Sox2, and Klf4 (OSK) Yamanaka factors induce pluripotency and reverse age-related epigenetic changes, yet the mechanisms by which they promote rejuvenation remain poorly explored. Oxidative stress contributes to CNS aging and retinal pigmented epithelium (RPE) degeneration in age-related macular degeneration. We find that OSK expression in RPE restores retinal structure and visual function in aged mice and promotes oxidative resilience through a non-canonical, Tet2-independent pathway. Integrative functional genomics identifies GSTA4, a detoxifying enzyme that clears the lipid peroxidation byproduct 4-HNE, as a necessary and sufficient OSK effector. Dynamic GSTA4 regulation by OSK recapitulates a stem cell derived stress resilience program. GSTA4 overexpression alone enhances mitochondrial resilience, rejuvenates the aged RPE transcriptome, and reverses visual decline. GSTA4 is consistently upregulated across diverse lifespan-extending interventions suggesting a broader pro-longevity role. These findings uncover a previously unrecognized protective axis driven by Yamanaka factors that circumvents reprogramming, providing therapeutic insights for age-related diseases.

HIGHLIGHTS

  • OSK–GSTA4 provides a dynamic, Tet2-independent stress-resilience axis.

  • Functional genomics pinpoints GSTA4 as a direct downstream effector activated by OSK.

  • RPE aging involves progressive accumulation of 4-HNE that can be detoxified by GSTA4.

  • Enhancing GSTA4 rejuvenates RPE cells, restores vision and is associated with lifespan-extending interventions.

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