Radioprotection of healthy tissue via nanoparticle-delivered mRNA encoding for a damage-suppressor protein found in tardigrades

Ameya R. Kirtane; Jianling Bi; Netra U. Rajesh; Chaoyang Tang; Miguel Jimenez; Emily Witt; Megan K. McGovern; Arielle B. Cafi; Samual J. Hatfield; Lauren Rosenstock; Sarah L. Becker; Nicole Machado; Veena Venkatachalam; Dylan Freitas; Xisha Huang; Alvin Chan; Aaron Lopes; Hyunjoon Kim; Nayoon Kim; Joy E. Collins; Michelle E. Howard; Srija Manchkanti; Theodore S. Hong; James D. Byrne; Giovanni Traverso

doi:10.1038/s41551-025-01360-5

Radioprotection of healthy tissue via nanoparticle-delivered mRNA encoding for a damage-suppressor protein found in tardigrades

Ameya R. Kirtane, Jianling Bi, Netra U. Rajesh, Chaoyang Tang, Miguel Jimenez, Emily Witt, Megan K. McGovern, Arielle B. Cafi, Samual J. Hatfield, Lauren Rosenstock, Sarah L. Becker, Nicole Machado, Veena Venkatachalam, Dylan Freitas, Xisha Huang, Alvin Chan, Aaron Lopes, Hyunjoon Kim, Nayoon Kim, Joy E. CollinsMichelle E. Howard, Srija Manchkanti, Theodore S. Hong, James D. Byrne, Giovanni Traverso

Research output: Contribution to journal › Article › peer-review

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Abstract

Patients undergoing radiation therapy experience debilitating side effects because of toxicity arising from radiation-induced DNA strand breaks in normal peritumoural cells. Here, inspired by the ability of tardigrades to resist extreme radiation through the expression of a damage-suppressor protein that binds to DNA and reduces strand breaks, we show that the local and transient expression of the protein can reduce radiation-induced DNA damage in oral and rectal epithelial tissues (which are commonly affected during radiotherapy for head-and-neck and prostate cancers, respectively). We used ionizable lipid nanoparticles supplemented with biodegradable cationic polymers to enhance the transfection efficiency and delivery of messenger RNA encoding the damage-suppressor protein into buccal and rectal tissues. In mice with orthotopic oral cancer, messenger RNA-based radioprotection of normal tissue preserved the efficacy of radiation therapy. The strategy may be broadly applicable to the protection of healthy tissue from DNA-damaging agents.

Original language	English (US)
Pages (from-to)	1240-1253
Number of pages	14
Journal	Nature Biomedical Engineering
Volume	9
Issue number	8
DOIs	https://doi.org/10.1038/s41551-025-01360-5
State	Published - Aug 2025
Externally published	Yes

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Publisher Copyright:
© The Author(s), under exclusive licence to Springer Nature Limited 2025.

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Kirtane, A. R., Bi, J., Rajesh, N. U., Tang, C., Jimenez, M., Witt, E., McGovern, M. K., Cafi, A. B., Hatfield, S. J., Rosenstock, L., Becker, S. L., Machado, N., Venkatachalam, V., Freitas, D., Huang, X., Chan, A., Lopes, A., Kim, H., Kim, N., ... Traverso, G. (2025). Radioprotection of healthy tissue via nanoparticle-delivered mRNA encoding for a damage-suppressor protein found in tardigrades. Nature Biomedical Engineering, 9(8), 1240-1253. https://doi.org/10.1038/s41551-025-01360-5

Kirtane, AR, Bi, J, Rajesh, NU, Tang, C, Jimenez, M, Witt, E, McGovern, MK, Cafi, AB, Hatfield, SJ, Rosenstock, L, Becker, SL, Machado, N, Venkatachalam, V, Freitas, D, Huang, X, Chan, A, Lopes, A, Kim, H, Kim, N, Collins, JE, Howard, ME, Manchkanti, S, Hong, TS, Byrne, JD & Traverso, G 2025, 'Radioprotection of healthy tissue via nanoparticle-delivered mRNA encoding for a damage-suppressor protein found in tardigrades', Nature Biomedical Engineering, vol. 9, no. 8, pp. 1240-1253. https://doi.org/10.1038/s41551-025-01360-5

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abstract = "Patients undergoing radiation therapy experience debilitating side effects because of toxicity arising from radiation-induced DNA strand breaks in normal peritumoural cells. Here, inspired by the ability of tardigrades to resist extreme radiation through the expression of a damage-suppressor protein that binds to DNA and reduces strand breaks, we show that the local and transient expression of the protein can reduce radiation-induced DNA damage in oral and rectal epithelial tissues (which are commonly affected during radiotherapy for head-and-neck and prostate cancers, respectively). We used ionizable lipid nanoparticles supplemented with biodegradable cationic polymers to enhance the transfection efficiency and delivery of messenger RNA encoding the damage-suppressor protein into buccal and rectal tissues. In mice with orthotopic oral cancer, messenger RNA-based radioprotection of normal tissue preserved the efficacy of radiation therapy. The strategy may be broadly applicable to the protection of healthy tissue from DNA-damaging agents.",

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doi = "10.1038/s41551-025-01360-5",

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AU - Witt, Emily

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AU - Hatfield, Samual J.

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AU - Machado, Nicole

AU - Venkatachalam, Veena

AU - Freitas, Dylan

AU - Huang, Xisha

AU - Chan, Alvin

AU - Lopes, Aaron

AU - Kim, Hyunjoon

AU - Kim, Nayoon

AU - Collins, Joy E.

AU - Howard, Michelle E.

AU - Manchkanti, Srija

AU - Hong, Theodore S.

AU - Byrne, James D.

AU - Traverso, Giovanni

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N2 - Patients undergoing radiation therapy experience debilitating side effects because of toxicity arising from radiation-induced DNA strand breaks in normal peritumoural cells. Here, inspired by the ability of tardigrades to resist extreme radiation through the expression of a damage-suppressor protein that binds to DNA and reduces strand breaks, we show that the local and transient expression of the protein can reduce radiation-induced DNA damage in oral and rectal epithelial tissues (which are commonly affected during radiotherapy for head-and-neck and prostate cancers, respectively). We used ionizable lipid nanoparticles supplemented with biodegradable cationic polymers to enhance the transfection efficiency and delivery of messenger RNA encoding the damage-suppressor protein into buccal and rectal tissues. In mice with orthotopic oral cancer, messenger RNA-based radioprotection of normal tissue preserved the efficacy of radiation therapy. The strategy may be broadly applicable to the protection of healthy tissue from DNA-damaging agents.

AB - Patients undergoing radiation therapy experience debilitating side effects because of toxicity arising from radiation-induced DNA strand breaks in normal peritumoural cells. Here, inspired by the ability of tardigrades to resist extreme radiation through the expression of a damage-suppressor protein that binds to DNA and reduces strand breaks, we show that the local and transient expression of the protein can reduce radiation-induced DNA damage in oral and rectal epithelial tissues (which are commonly affected during radiotherapy for head-and-neck and prostate cancers, respectively). We used ionizable lipid nanoparticles supplemented with biodegradable cationic polymers to enhance the transfection efficiency and delivery of messenger RNA encoding the damage-suppressor protein into buccal and rectal tissues. In mice with orthotopic oral cancer, messenger RNA-based radioprotection of normal tissue preserved the efficacy of radiation therapy. The strategy may be broadly applicable to the protection of healthy tissue from DNA-damaging agents.

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Radioprotection of healthy tissue via nanoparticle-delivered mRNA encoding for a damage-suppressor protein found in tardigrades

Abstract

Bibliographical note

PubMed: MeSH publication types

UN SDGs

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