Chemotherapeutic agents and leucine deprivation induce codon-biased aberrant protein production in cancer

Adva Kochavi; Remco Nagel; Pierre-Rene Korner; Onno B. Bleijerveld; Chun-Pu Lin; Zowi Huinen; Yuval Malka; Natalie Proost; Marieke van de Ven; Xiaodong Feng; Jasmine Montenegro Navarro; Abhijeet Pataskar; Daniel S. Peeper; Julien Champagne; Reuven Agami

doi:10.1093/nar/gkae1110

Chemotherapeutic agents and leucine deprivation induce codon-biased aberrant protein production in cancer

Adva Kochavi, Remco Nagel, Pierre-Rene Korner, Onno B. Bleijerveld, Chun-Pu Lin, Zowi Huinen, Yuval Malka, Natalie Proost, Marieke van de Ven, Xiaodong Feng, Jasmine Montenegro Navarro, Abhijeet Pataskar, Daniel S. Peeper, Julien Champagne, Reuven Agami^*

^*Corresponding author for this work

Molecular Genetics

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

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Abstract

Messenger RNA (mRNA) translation is a tightly controlled process frequently deregulated in cancer. Key to this deregulation are transfer RNAs (tRNAs), whose expression, processing and post-transcriptional modifications are often altered in cancer to support cellular transformation. In conditions of limiting levels of amino acids, this deregulated control of protein synthesis leads to aberrant protein production in the form of ribosomal frameshifting or misincorporation of non-cognate amino acids. Here, we studied leucine, an essential amino acid coded by six different codons. Surprisingly, we found that leucine deprivation leads to ribosomal stalling and aberrant protein production in various cancer cell types, predominantly at one codon, UUA. Similar effects were observed after treatment with chemotherapeutic agents, implying a shared mechanism controlling the downstream effects on mRNA translation. In both conditions, a limitation in the availability of tRNA ^Leu(UAA) for protein production was shown to be the cause for this dominant effect on UUA codons. The induced aberrant proteins can be processed and immune-presented as neoepitopes and can direct T-cell killing. Altogether, we uncovered a novel mode of interplay between DNA damage, regulation of tRNA availability for mRNA translation and aberrant protein production in cancer that could be exploited for anti-cancer therapy.

Original language	English
Article number	gkae1110
Pages (from-to)	13964–13979
Number of pages	16
Journal	Nucleic Acids Research
Volume	52
Issue number	22
Early online date	26 Nov 2024
DOIs	https://doi.org/10.1093/nar/gkae1110
Publication status	Published - 11 Dec 2024

Bibliographical note

Publisher Copyright:
© The Author(s) 2024. Published by Oxford University Press on behalf of Nucleic Acids Research.

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Kochavi, A., Nagel, R., Korner, P.-R., Bleijerveld, O. B., Lin, C.-P., Huinen, Z., Malka, Y., Proost, N., van de Ven, M., Feng, X., Navarro, J. M., Pataskar, A., Peeper, D. S., Champagne, J., & Agami, R. (2024). Chemotherapeutic agents and leucine deprivation induce codon-biased aberrant protein production in cancer. Nucleic Acids Research, 52(22), 13964–13979. Article gkae1110. https://doi.org/10.1093/nar/gkae1110

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title = "Chemotherapeutic agents and leucine deprivation induce codon-biased aberrant protein production in cancer",

abstract = "Messenger RNA (mRNA) translation is a tightly controlled process frequently deregulated in cancer. Key to this deregulation are transfer RNAs (tRNAs), whose expression, processing and post-transcriptional modifications are often altered in cancer to support cellular transformation. In conditions of limiting levels of amino acids, this deregulated control of protein synthesis leads to aberrant protein production in the form of ribosomal frameshifting or misincorporation of non-cognate amino acids. Here, we studied leucine, an essential amino acid coded by six different codons. Surprisingly, we found that leucine deprivation leads to ribosomal stalling and aberrant protein production in various cancer cell types, predominantly at one codon, UUA. Similar effects were observed after treatment with chemotherapeutic agents, implying a shared mechanism controlling the downstream effects on mRNA translation. In both conditions, a limitation in the availability of tRNA Leu(UAA) for protein production was shown to be the cause for this dominant effect on UUA codons. The induced aberrant proteins can be processed and immune-presented as neoepitopes and can direct T-cell killing. Altogether, we uncovered a novel mode of interplay between DNA damage, regulation of tRNA availability for mRNA translation and aberrant protein production in cancer that could be exploited for anti-cancer therapy.",

author = "Adva Kochavi and Remco Nagel and Pierre-Rene Korner and Bleijerveld, {Onno B.} and Chun-Pu Lin and Zowi Huinen and Yuval Malka and Natalie Proost and {van de Ven}, Marieke and Xiaodong Feng and Navarro, {Jasmine Montenegro} and Abhijeet Pataskar and Peeper, {Daniel S.} and Julien Champagne and Reuven Agami",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024. Published by Oxford University Press on behalf of Nucleic Acids Research.",

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doi = "10.1093/nar/gkae1110",

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Kochavi, A, Nagel, R, Korner, P-R, Bleijerveld, OB, Lin, C-P, Huinen, Z, Malka, Y, Proost, N, van de Ven, M, Feng, X, Navarro, JM, Pataskar, A, Peeper, DS, Champagne, J & Agami, R 2024, 'Chemotherapeutic agents and leucine deprivation induce codon-biased aberrant protein production in cancer', Nucleic Acids Research, vol. 52, no. 22, gkae1110, pp. 13964–13979. https://doi.org/10.1093/nar/gkae1110

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T1 - Chemotherapeutic agents and leucine deprivation induce codon-biased aberrant protein production in cancer

AU - Kochavi, Adva

AU - Nagel, Remco

AU - Korner, Pierre-Rene

AU - Bleijerveld, Onno B.

AU - Lin, Chun-Pu

AU - Huinen, Zowi

AU - Malka, Yuval

AU - Proost, Natalie

AU - van de Ven, Marieke

AU - Feng, Xiaodong

AU - Navarro, Jasmine Montenegro

AU - Pataskar, Abhijeet

AU - Peeper, Daniel S.

AU - Champagne, Julien

AU - Agami, Reuven

PY - 2024/12/11

Y1 - 2024/12/11

N2 - Messenger RNA (mRNA) translation is a tightly controlled process frequently deregulated in cancer. Key to this deregulation are transfer RNAs (tRNAs), whose expression, processing and post-transcriptional modifications are often altered in cancer to support cellular transformation. In conditions of limiting levels of amino acids, this deregulated control of protein synthesis leads to aberrant protein production in the form of ribosomal frameshifting or misincorporation of non-cognate amino acids. Here, we studied leucine, an essential amino acid coded by six different codons. Surprisingly, we found that leucine deprivation leads to ribosomal stalling and aberrant protein production in various cancer cell types, predominantly at one codon, UUA. Similar effects were observed after treatment with chemotherapeutic agents, implying a shared mechanism controlling the downstream effects on mRNA translation. In both conditions, a limitation in the availability of tRNA Leu(UAA) for protein production was shown to be the cause for this dominant effect on UUA codons. The induced aberrant proteins can be processed and immune-presented as neoepitopes and can direct T-cell killing. Altogether, we uncovered a novel mode of interplay between DNA damage, regulation of tRNA availability for mRNA translation and aberrant protein production in cancer that could be exploited for anti-cancer therapy.

AB - Messenger RNA (mRNA) translation is a tightly controlled process frequently deregulated in cancer. Key to this deregulation are transfer RNAs (tRNAs), whose expression, processing and post-transcriptional modifications are often altered in cancer to support cellular transformation. In conditions of limiting levels of amino acids, this deregulated control of protein synthesis leads to aberrant protein production in the form of ribosomal frameshifting or misincorporation of non-cognate amino acids. Here, we studied leucine, an essential amino acid coded by six different codons. Surprisingly, we found that leucine deprivation leads to ribosomal stalling and aberrant protein production in various cancer cell types, predominantly at one codon, UUA. Similar effects were observed after treatment with chemotherapeutic agents, implying a shared mechanism controlling the downstream effects on mRNA translation. In both conditions, a limitation in the availability of tRNA Leu(UAA) for protein production was shown to be the cause for this dominant effect on UUA codons. The induced aberrant proteins can be processed and immune-presented as neoepitopes and can direct T-cell killing. Altogether, we uncovered a novel mode of interplay between DNA damage, regulation of tRNA availability for mRNA translation and aberrant protein production in cancer that could be exploited for anti-cancer therapy.

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DO - 10.1093/nar/gkae1110

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JO - Nucleic Acids Research

JF - Nucleic Acids Research

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M1 - gkae1110

ER -

Chemotherapeutic agents and leucine deprivation induce codon-biased aberrant protein production in cancer

Abstract

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