Targeting mitochondrial translation by inhibiting DDX3: A novel radiosensitization strategy for cancer treatment

M. R. Heerma Van Voss; F. Vesuna; G. M. Bol; J. Afzal; S. Tantravedi; Y. Bergman; K. Kammers; M. Lehar; R. Malek; M. Ballew; N. Ter Hoeve; D. Abou; D. Thorek; C. Berlinicke; M. Yazdankhah; D. Sinha; A. Le; R. Abrahams; P. T. Tran; P. J. Van Diest; V. Raman

doi:10.1038/onc.2017.308

Targeting mitochondrial translation by inhibiting DDX3: A novel radiosensitization strategy for cancer treatment

M. R. Heerma Van Voss, F. Vesuna, G. M. Bol, J. Afzal, S. Tantravedi, Y. Bergman, K. Kammers, M. Lehar, R. Malek, M. Ballew, N. Ter Hoeve, D. Abou, D. Thorek, C. Berlinicke, M. Yazdankhah, D. Sinha, A. Le, R. Abrahams, P. T. Tran, P. J. Van DiestV. Raman

School of Medicine

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

26 Scopus citations

Abstract

DDX3 is a DEAD box RNA helicase with oncogenic properties. RK-33 is developed as a small-molecule inhibitor of DDX3 and showed potent radiosensitizing activity in preclinical tumor models. This study aimed to assess DDX3 as a target in breast cancer and to elucidate how RK-33 exerts its anti-neoplastic effects. High DDX3 expression was present in 35% of breast cancer patient samples and correlated with markers of aggressiveness and shorter survival. With a quantitative proteomics approach, we identified proteins involved in the mitochondrial translation and respiratory electron transport pathways to be significantly downregulated after RK-33 or DDX3 knockdown. DDX3 localized to the mitochondria and DDX3 inhibition with RK-33 reduced mitochondrial translation. As a consequence, oxygen consumption rates and intracellular ATP concentrations decreased and reactive oxygen species (ROS) increased. RK-33 antagonized the increase in oxygen consumption and ATP production observed after exposure to ionizing radiation and reduced DNA repair. Overall, we conclude that DDX3 inhibition with RK-33 causes radiosensitization in breast cancer through inhibition of mitochondrial translation, which results in reduced oxidative phosphorylation capacity and increased ROS levels, culminating in a bioenergetic catastrophe.

Original language	English (US)
Pages (from-to)	63-74
Number of pages	12
Journal	Oncogene
Volume	37
Issue number	1
DOIs	https://doi.org/10.1038/onc.2017.308
State	Published - Jan 4 2018

ASJC Scopus subject areas

Molecular Biology
Genetics
Cancer Research

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Heerma Van Voss, M. R., Vesuna, F., Bol, G. M., Afzal, J., Tantravedi, S., Bergman, Y., Kammers, K., Lehar, M., Malek, R., Ballew, M., Ter Hoeve, N., Abou, D., Thorek, D., Berlinicke, C., Yazdankhah, M., Sinha, D., Le, A., Abrahams, R., Tran, P. T., ... Raman, V. (2018). Targeting mitochondrial translation by inhibiting DDX3: A novel radiosensitization strategy for cancer treatment. Oncogene, 37(1), 63-74. https://doi.org/10.1038/onc.2017.308

Heerma Van Voss, MR, Vesuna, F, Bol, GM, Afzal, J, Tantravedi, S, Bergman, Y, Kammers, K , Lehar, M, Malek, R, Ballew, M, Ter Hoeve, N, Abou, D, Thorek, D, Berlinicke, C, Yazdankhah, M, Sinha, D, Le, A, Abrahams, R, Tran, PT, Van Diest, PJ & Raman, V 2018, 'Targeting mitochondrial translation by inhibiting DDX3: A novel radiosensitization strategy for cancer treatment', Oncogene, vol. 37, no. 1, pp. 63-74. https://doi.org/10.1038/onc.2017.308

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abstract = "DDX3 is a DEAD box RNA helicase with oncogenic properties. RK-33 is developed as a small-molecule inhibitor of DDX3 and showed potent radiosensitizing activity in preclinical tumor models. This study aimed to assess DDX3 as a target in breast cancer and to elucidate how RK-33 exerts its anti-neoplastic effects. High DDX3 expression was present in 35% of breast cancer patient samples and correlated with markers of aggressiveness and shorter survival. With a quantitative proteomics approach, we identified proteins involved in the mitochondrial translation and respiratory electron transport pathways to be significantly downregulated after RK-33 or DDX3 knockdown. DDX3 localized to the mitochondria and DDX3 inhibition with RK-33 reduced mitochondrial translation. As a consequence, oxygen consumption rates and intracellular ATP concentrations decreased and reactive oxygen species (ROS) increased. RK-33 antagonized the increase in oxygen consumption and ATP production observed after exposure to ionizing radiation and reduced DNA repair. Overall, we conclude that DDX3 inhibition with RK-33 causes radiosensitization in breast cancer through inhibition of mitochondrial translation, which results in reduced oxidative phosphorylation capacity and increased ROS levels, culminating in a bioenergetic catastrophe.",

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AU - Heerma Van Voss, M. R.

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AU - Bol, G. M.

AU - Afzal, J.

AU - Tantravedi, S.

AU - Bergman, Y.

AU - Kammers, K.

AU - Lehar, M.

AU - Malek, R.

AU - Ballew, M.

AU - Ter Hoeve, N.

AU - Abou, D.

AU - Thorek, D.

AU - Berlinicke, C.

AU - Yazdankhah, M.

AU - Sinha, D.

AU - Le, A.

AU - Abrahams, R.

AU - Tran, P. T.

AU - Van Diest, P. J.

AU - Raman, V.

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Targeting mitochondrial translation by inhibiting DDX3: A novel radiosensitization strategy for cancer treatment

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