Author
Listed:
- Jordan S. Kesner
(Columbia University Irving Medical Center
Columbia University Irving Medical Center)
- Ziheng Chen
(Columbia University Irving Medical Center
Columbia University Irving Medical Center
Carnegie Mellon University)
- Peiguo Shi
(Columbia University Irving Medical Center
Columbia University Irving Medical Center)
- Alexis O. Aparicio
(Columbia University Irving Medical Center
Columbia University Irving Medical Center)
- Michael R. Murphy
(Columbia University Irving Medical Center
Columbia University Irving Medical Center)
- Yang Guo
(Columbia University Irving Medical Center
Columbia University Irving Medical Center)
- Aditi Trehan
(Columbia University Irving Medical Center
Columbia University Irving Medical Center)
- Jessica E. Lipponen
(Columbia University Irving Medical Center)
- Yocelyn Recinos
(Columbia University Irving Medical Center)
- Natura Myeku
(Columbia University Irving Medical Center)
- Xuebing Wu
(Columbia University Irving Medical Center
Columbia University Irving Medical Center)
Abstract
Translation is pervasive outside of canonical coding regions, occurring in long noncoding RNAs, canonical untranslated regions and introns1–4, especially in ageing4–6, neurodegeneration5,7 and cancer8–10. Notably, the majority of tumour-specific antigens are results of noncoding translation11–13. Although the resulting polypeptides are often nonfunctional, translation of noncoding regions is nonetheless necessary for the birth of new coding sequences14,15. The mechanisms underlying the surveillance of translation in diverse noncoding regions and how escaped polypeptides evolve new functions remain unclear10,16–19. Functional polypeptides derived from annotated noncoding sequences often localize to membranes20,21. Here we integrate massively parallel analyses of more than 10,000 human genomic sequences and millions of random sequences with genome-wide CRISPR screens, accompanied by in-depth genetic and biochemical characterizations. Our results show that the intrinsic nucleotide bias in the noncoding genome and in the genetic code frequently results in polypeptides with a hydrophobic C-terminal tail, which is captured by the ribosome-associated BAG6 membrane protein triage complex for either proteasomal degradation or membrane targeting. By contrast, canonical proteins have evolved to deplete C-terminal hydrophobic residues. Our results reveal a fail-safe mechanism for the surveillance of unwanted translation from diverse noncoding regions and suggest a possible biochemical route for the preferential membrane localization of newly evolved proteins.
Suggested Citation
Jordan S. Kesner & Ziheng Chen & Peiguo Shi & Alexis O. Aparicio & Michael R. Murphy & Yang Guo & Aditi Trehan & Jessica E. Lipponen & Yocelyn Recinos & Natura Myeku & Xuebing Wu, 2023.
"Noncoding translation mitigation,"
Nature, Nature, vol. 617(7960), pages 395-402, May.
Handle:
RePEc:nat:nature:v:617:y:2023:i:7960:d:10.1038_s41586-023-05946-4
DOI: 10.1038/s41586-023-05946-4
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Citations
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Cited by:
- Haiwang Yang & Qianru Li & Emily K. Stroup & Sheng Wang & Zhe Ji, 2024.
"Widespread stable noncanonical peptides identified by integrated analyses of ribosome profiling and ORF features,"
Nature Communications, Nature, vol. 15(1), pages 1-18, December.
- Avantika Ghosh & Marisa Riester & Jagriti Pal & Kadri-Ann Lainde & Carla Tangermann & Angela Wanninger & Ursula K. Dueren & Sonam Dhamija & Sven Diederichs, 2024.
"Suppressive cancer nonstop extension mutations increase C-terminal hydrophobicity and disrupt evolutionarily conserved amino acid patterns,"
Nature Communications, Nature, vol. 15(1), pages 1-16, December.
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