Dynamic Ribosomal RNA Methylation Regulates Translation in the Hematopoietic System and is Essential for Stem Cell Fitness

  1. Ofri Rabany
  2. Sivan Ben Dror
  3. Maram Arafat
  4. Hadar Aharoni
  5. Yudit Halperin
  6. Virginie Marchand
  7. Nikolai Romanovski
  8. Noga Ussishkin
  9. Maayan Livneh
  10. Adi Reches
  11. Judith Wexler
  12. Nina Mayorek
  13. Galia Monderer-Rothkoff
  14. Sagiv Shifman
  15. Widad Mammer Bouhou
  16. Michael VanInsberghe
  17. Cornelius Pauli
  18. Carsten Müller-Tidow
  19. Ola Karmi
  20. Yoav Livneh
  21. Alexander van Oudenaarden
  22. Yuri Motorin
  23. Daphna Nachmani
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Abstract

Self-renewal and differentiation are at the basis of hematopoiesis. While it is known that tight regulation of translation is vital for hematopoietic stem cells’ (HSCs) biology, the mechanisms underlying translation regulation across the hematopoietic system remain obscure. Here we reveal a novel mechanism of translation regulation in the hematopoietic hierarchy, which is mediated by ribosomal RNA (rRNA) methylation dynamics.

Using ultra-low input ribosome-profiling, we characterized cell-type-specific translation capacity during erythroid differentiation. We found that translation efficiency changes progressively with differentiation and can distinguish between discrete cell populations as well as to define differentiation trajectories. To reveal the underlying mechanism, we performed comprehensive mapping of the most abundant rRNA modification - 2’-O-methyl (2’OMe). We found that, like translation efficiency, 2’OMe dynamics followed a distinct trajectory during erythroid differentiation.

Genetic perturbation of individual 2’OMe sites demonstrated their distinct roles in modulating proliferation and differentiation. By combining CRISPR screening, molecular and functional analyses, we identified a specific methylation site, 28S-Gm4588, which is progressively lost during differentiation, as a key regulator of HSC self-renewal. We showed that low methylation at this site led to translational skewing, mediated mainly by codon frequency, which promoted differentiation. Functionally, HSCs with diminished 28S-Gm4588 methylation exhibited impaired self-renewal capacity ex-vivo , and loss of fitness in-vivo in bone marrow transplantations.

Extending our findings beyond the hematopoietic system, we also found distinct dynamics of 2’OMe profiles during differentiation of non-hematopoietic stem cells. Our findings reveal rRNA methylation dynamics as a general mechanism for cell-type-specific translation, required for cell function and differentiation.

KEY POINTS

  • Hematopoietic differentiation is associated with rRNA methylation dynamics to control cell-type-specific translation.

  • Translation efficiency can distinguish discrete cell types and define differentiation trajectories.

  • HSC fitness is regulated by a single rRNA methylation.

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    1. Version published to 10.1101/2025.09.29.679281 on bioRxiv