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    Journals >Journal of Radiation Research and Radiation Processing >Volume 41 >Issue 3 >Page 030101 > Article
    • Journal of Radiation Research and Radiation Processing
    • Vol. 41, Issue 3, 030101 (2023)
    Progress of research on double-strand break damage induced by heavy-ion beam radiation and repair mechanism
    Junle REN1,2, Xiaopeng GUO3, Cairong LEI1,2, Miaomiao ZHANG1,2,4..., Ran CHAI3 and Dong LU1,2,4,*|Show fewer author(s)
    Author Affiliations
  • 1Institute of Modern Physics, Chinese Academy of Sciences, Lanzhou 730000, China
  • 2University of Chinese Academy of Sciences, Beijing 100049, China
  • 3Lanzhou University of Technology, Lanzhou 730050, China
  • 4Key Laboratory of Microbial Resources Development and Utilization of Gansu Province, Lanzhou 730070, China
    • show less
    DOI: 10.11889/j.1000-3436.2022-0081 Cite this Article
    Junle REN, Xiaopeng GUO, Cairong LEI, Miaomiao ZHANG, Ran CHAI, Dong LU. Progress of research on double-strand break damage induced by heavy-ion beam radiation and repair mechanism[J]. Journal of Radiation Research and Radiation Processing, 2023, 41(3): 030101 Copy Citation Text show less
    References

    [1] Jianshun MIAO, Jianshe YANG, Miaomiao ZHANG et al. Microbial mutagenic effects and mutation breeding advances induced by heavy ion beams. Journal of Radiation Research and Radiation Processing, 32, 3-10(2014).

    [2] M Durante, R Orecchia, J S Loeffler. Charged-particle therapy in cancer: clinical uses and future perspectives. NatureReviewsClinicalOncology, 14, 483-495(2017).

    [3] X Zhang, F Yang, H Y Ma et al. Evaluation of the saline-alkaline tolerance of rice (Oryza sativa L.) mutants induced by heavy-ion beam mutagenesis. Biology, 11, 126(2022).

    [4] Ying WEN, Xue YU, Yujie WU et al. Advanced in microbial breeding by heavy ion mutation. Journal of Microbiology, 41, 66-74(2021).

    [5] S Ritter, M Durante. Heavy-ion induced chromosomal aberrations: a review. Mutation Research, 701, 38-46(2010).

    [6] A Pompos, R L Foote, A C Koong et al. National effort to re-establish heavy ion cancer therapy in the United States. Front Oncol, 12, 880712(2022).

    [7] H Nikjoo, P O'Neill, W E Wilson et al. Computational approach for determining the spectrum of DNA damage induced by ionizing radiation. Radiation Research, 156, 577-583(2001).

    [8] W Friedland, E Schmitt, P Kundrát et al. Comprehensive track-structure based evaluation of DNA damage by light ions from radiotherapy-relevant energies down to stopping. ScientificReports, 7, 45161(2017).

    [9] M Aoki-Nakano, Y Furusawa. Misrepair of DNA double-strand breaks after exposure to heavy-ion beams causes a peak in the LET-RBE relationship with respect to cell killing in DT40 cells. Journal of Radiation Research, 54, 1029-1035(2013).

    [10] N Lampe, M Karamitros, V Breton et al. Mechanistic DNA damage simulations in Geant4-DNA Part 2: electron and proton damage in a bacterial cell. Physica Medica: PM: an International Journal Devoted to the Applications of Physics to Medicine and Biology: Official Journal of the Italian Association of Biomedical Physics (AIFB), 48, 146-155(2018).

    [11] E M Taylor, A R Lehmann. Conservation of eukaryotic DNA repair mechanisms. International Journal of Radiation Biology, 74, 277-286(1998).

    [12] J H J Hoeijmakers. Genome maintenance mechanisms for preventing cancer. Nature, 411, 366-374(2001).

    [13] W L Santivasi, F Xia. Ionizing radiation-induced DNA damage, response, and repair. Antioxidants & Redox Signaling, 21, 251-259(2014).

    [14] A Schipler, G Iliakis. DNA double-strand-break complexity levels and their possible contributions to the probability for error-prone processing and repair pathway choice. Nucleic Acids Research, 41, 7589-7605(2013).

    [15] E Mladenov, S Magin, A Soni et al. DNA double-strand-break repair in higher eukaryotes and its role in genomic instability and cancer: cell cycle and proliferation-dependent regulation. Seminars in Cancer Biology, 37/38, 51-64(2016).

    [16] S Burma, B P C Chen, D J Chen. Role of non-homologous end joining (NHEJ) in maintaining genomic integrity. DNA Repair, 5, 1042-1048(2006).

    [17] G Iliakis, E Mladenov, V Mladenova. Necessities in the processing of DNA double strand breaks and their effects on genomic instability and cancer. Cancers, 11, 1671(2019).

    [18] R Scully, A Panday, R Elango et al. DNA double-strand break repair-pathway choice in somatic mammalian cells. Nature Reviews Molecular Cell Biology, 20, 698-714(2019).

    [19] K I Masumura, K Kuniya, T Kurobe et al. Heavy-ion-induced mutations in the gpt delta transgenic mouse: comparison of mutation spectra induced by heavy-ion, X-ray, and gamma-ray radiation. Environmental and Molecular Mutagenesis, 40, 207-215(2002).

    [20] F Yatagai. Mutations induced by heavy charged particles. Biological Sciences in Space, 18, 224-234(2004).

    [21] E Gollapalle, R Wang, R Adetolu et al. Detection of oxidative clustered DNA lesions in X-irradiated mouse skin tissues and human MCF-7 breast cancer cells. Radiation Research, 167, 207-216(2007).

    [22] R J Carter, C M Nickson, J M Thompson et al. Complex DNA damage induced by high linear energy transfer alpha-particles and protons triggers a specific cellular DNA damage response. International Journal of Radiation Oncology*Biology*Physics, 100, 776-784(2018).

    [23] B M Sutherland, P V Bennett, J C Sutherland et al. Clustered DNA damages induced by xrays in human cells. Radiation Research, 157, 611-616(2002).

    [24] A Asaithamby, B R Hu, D J Chen. Unrepaired clustered DNA lesions induce chromosome breakage in human cells. Proceedings of the National Academy of Sciences of the United States of America, 108, 8293-8298(2011).

    [25] Y Hagiwara, T Oike, A Niimi et al. Clustered DNA double-strand break formation and the repair pathway following heavy-ion irradiation. Journal of Radiation Research, 60, 69-79(2019).

    [26] E Soutoglou, J F Dorn, K Sengupta et al. Positional stability of single double-strand breaks in mammalian cells. Nature Cell Biology, 9, 675-682(2007).

    [27] N Desai, E Davis, P O'Neill et al. Immunofluorescence detection of clustered gamma-H2AX foci induced by HZE-particle radiation. Radiation Research, 164, 518-522(2005).

    [28] N I Nakajima, H Brunton, R Watanabe et al. Visualisation of γH2AX foci caused by heavy ion particle traversal; distinction between core track versus non-track damage. PLoS One, 8, e70107(2013).

    [29] T Oike, A Niimi, N Okonogi et al. Visualization of complex DNA double-strand breaks in a tumor treated with carbon ion radiotherapy. Scientific Reports, 6, 22275(2016).

    [30] L Zhao, C Bao, Y Shang et al. The determinant of DNA repair pathway choices in ionising radiation-induced DNA double-strand breaks. BioMed Research International, 2020, 4834965(2020).

    [31] S E Lee, J K Moore, A Holmes et al. Saccharomyces Ku70, mre11/rad50 and RPA proteins regulate adaptation to G2/M arrest after DNA damage. Cell, 94, 399-409(1998).

    [32] Y Matuo, Y Izumi, Y Furusawa et al. Biological effects of carbon ion beams with various LETs on budding yeast Saccharomyces cerevisiae. Mutation Research/Fundamental and Molecular Mechanisms of Mutagenesis, 810, 45-51(2018).

    [33] X P Guo, M M Zhang, Y Gao et al. Repair characteristics and time-dependent effects in response to heavy-ion beam irradiation in Saccharomyces cerevisiae: a comparison with X-ray irradiation. Applied Microbiology and Biotechnology, 104, 4043-4057(2020).

    [34] R Bhargava, D O Onyango, J M Stark. Regulation of single-strandannealing and its role in genome maintenance. Trends in Genetics: TIG, 32, 566-575(2016).

    [35] A Shibata, S Conrad, J Birraux et al. Factors determining DNA double-strand break repair pathway choice in G2 phase. The EMBO Journal, 30, 1079-1092(2011).

    [36] H Yajima, H Fujisawa, N I Nakajima et al. The complexity of DNA double strand breaks is a critical factor enhancing end-resection. DNA Repair, 12, 936-946(2013).

    [37] D M Sridharan, A Asaithamby, S M Bailey et al. Understanding cancer development processes after HZE-particle exposure: roles of ROS, DNA damage repair and inflammation. Radiation Research, 183, 1-26(2015).

    [38] M Shrivastav, L P De Haro, J A Nickoloff. Regulation of DNA double-strand break repair pathway choice. Cell Research, 18, 134-147(2008).

    [39] J Reindl, S Girst, D W M Walsh et al. Chromatin organization revealed by nanostructure of irradiation induced γH2AX, 53BP1 and Rad51 foci. Scientific Reports, 7, 40616(2017).

    [40] D M Sridharan, M K Whalen, D Almendrala et al. Increased Artemis levels confer radioresistance to both high and low LET radiation exposures. Radiation Oncology (London, England), 7, 96(2012).

    [41] H Wang, X Wang, P Zhang et al. The Ku-dependent non-homologous end-joining but not other repair pathway is inhibited by high linear energy transfer ionizing radiation. DNA Repair, 7, 725-733(2008).

    [42] A Kalousi, E Soutoglou. Nuclear compartmentalization of DNA repair. Current Opinion in Genetics & Development, 37, 148-157(2016).

    [43] L Krenning, J van den Berg, R H Medema. Life or death after a break: what determines the choice?. Molecular Cell, 76, 346-358(2019).

    [44] F Aymard, M Aguirrebengoa, E Guillou et al. Genome-wide mapping of long-range contacts unveils clustering of DNA double-strand breaks at damaged active genes. Nature Structural & Molecular Biology, 24, 353-361(2017).

    [45] C Lemaître, A Grabarz, K Tsouroula et al. Nuclear position dictates DNA repair pathway choice. Genes & Development, 28, 2450-2463(2014).

    [46] A A Goodarzi, A T Noon, D Deckbar et al. ATM signaling facilitates repair of DNA double-strand breaks associated with heterochromatin. Molecular Cell, 31, 167-177(2008).

    [47] L F Povirk, T Zhou, R Z Zhou et al. Processing of 3'-phosphoglycolate-terminated DNA double strand breaks by Artemis nuclease. Journal of Biological Chemistry, 282, 3547-3558(2007).

    [48] S Panier, S J Boulton. Double-strand break repair: 53BP1 comes into focus. Nature Reviews Molecular Cell Biology, 15, 7-18(2014).

    [49] E Bártová, S Legartová, M Dundr et al. A role of the 53BP1 protein in genome protection: structural and functional characteristics of 53BP1-dependent DNA repair. Aging, 11, 2488-2511(2019).

    [50] J R Chapman, A J Sossick, S J Boulton et al. BRCA1-associated exclusion of 53BP1 from DNA damage sites underlies temporal control of DNA repair. Journal of Cell Science, 125, 3529-3534(2012).

    [51] R Gupta, K Somyajit, T Narita et al. DNA repair network analysis reveals shieldin as a key regulator of NHEJ and PARP inhibitor sensitivity. Cell, 173, 972-988.e23(2018).

    [52] B Schwarz, A A Friedl, S Girst et al. Nanoscopic analysis of 53BP1, BRCA1 and Rad51 reveals new insights in temporal progression of DNA-repair and pathway choice. Mutation Research/Fundamental and Molecular Mechanisms of Mutagenesis, 816, 111675(2019).

    [53] N B Averbeck, O Ringel, M Herrlitz et al. DNA end resection is needed for the repair of complex lesions in G1-phase human cells. Cell Cycle (Georgetown, Tex), 13, 2509-2516(2014).

    [54] W Wu, M Wang, W Wu et al. Repair of radiation induced DNA double strand breaks by backup NHEJ is enhanced in G2. DNA Repair, 7, 329-338(2008).

    [55] M L Wang, W Z Wu, W Q Wu et al. PARP-1 and Ku compete for repair of DNA double strand breaks by distinct NHEJ pathways. Nucleic Acids Research, 34, 6170-6182(2006).

    [56] N Hustedt, D Durocher. The control of DNA repair by the cell cycle. Nature Cell Biology, 19, 1-9(2017).

    [57] Y Aylon, B Liefshitz, M Kupiec. The CDK regulates repair of double-strand breaks by homologous recombination during the cell cycle. The EMBO Journal, 23, 4868-4875(2004).

    [58] P Huertas, F Cortés-Ledesma, A A Sartori et al. CDK targets Sae2 to control DNA-end resection and homologous recombination. Nature, 455, 689-692(2008).

    [59] N Tomimatsu, B Mukherjee, M Catherine Hardebeck et al. Phosphorylation of EXO1 by CDKs 1 and 2 regulates DNA end resection and repair pathway choice. Nature Communications, 5, 3561(2014).

    [60] A K Weimer, S Biedermann, A Schnittger. Specialization of CDK regulation under DNA damage. Cell Cycle (Georgetown, Tex), 16, 143-144(2017).

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    Junle REN, Xiaopeng GUO, Cairong LEI, Miaomiao ZHANG, Ran CHAI, Dong LU. Progress of research on double-strand break damage induced by heavy-ion beam radiation and repair mechanism[J]. Journal of Radiation Research and Radiation Processing, 2023, 41(3): 030101
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