[1] L J Stadler. Mutations in barley induced by X-rays and radium. Science, 68, 186-187(1928).

[2] Qu LIANG, Meixu GAO. Status and prospect of nuclear application for food and agriculture. Journal of Nuclear Agricultural Sciences, 38, 1-10(2024).

[3] Defa GU, Meiyu XU, Quanqing CHEN. New rice varieties FJR 832 and FBGR 861 bred with radiation of soft-X-ray. Acta Agriculturae Shanghai, 8, 20-24(1992).

[4] Zhaosong LIN. A new rice variety "Juanye Bai" bred by neutron mutagenesis. Journal of Nuclear Agricultural Sciences, 62(1981).

[5] Yingwu XIA, Zhongxin FAN, Tianming TANG. Breeding and application of rice mutant variety Zhefu 802. Application of Atomic Energy in Agriculture, 21-24(1986).

[6] S Ishikawa, T Abe, M Kuramata et al. Development of low-cadmium-accumulating rice. Himeno S, Aoshima K.Cadmium Toxicity, 139-150(2019).

[7] Jingpeng LI, Lixia YU, Xin ZHANG et al. Breeding and application of a new rice variety Dongdao-122. North Rice, 51, 44-47(2021).

[8] Yongzhu LIU, Zhiqiang CHEN, Jianguo ZHANG et al. Breeding of“Hanghui No.7”, a wide restorer line of rice by space mutation and its utilization. Journal of Nuclear Agricultural Sciences, 22, 439-442(2008).

[9] Fengshou ZHANG, Qing WANG. Research progresses in the plant breeding of radiation mutation. Journal of Henan Normal University (Natural Science Edition), 48, 39-49(2020).

[10] Y Hase, K Satoh, H Seito et al. Genetic consequences of acute/chronic gamma and carbon ion irradiation of Arabidopsis thaliana. Frontiers in Plant Science, 11, 336(2020).

[11] T K Mohanta, A K Mishra, Y K Mohanta et al. Space breeding: the next-generation crops. Frontiers in Plant Science, 12, 771985(2021).

[12] Zhiqiang CHEN, Danhua ZHOU, Tao GUO et al. Research progress of rice space mutation bio-breeding. Journal of South China Agricultural University, 40, 195-202(2019).

[13] Zhiqiang CHEN, Danhua ZHOU, Tao GUO et al. Development and prospect of plant space breeding. Satellite Application, 19-24(2021).

[14] Y Oladosu, M Y Rafii, N Abdullah et al. Principle and application of plant mutagenesis in crop improvement: a review. Biotechnology & Biotechnological Equipment, 30, 1-16(2016).

[15] Y Kazama, T Hirano, H Saito et al. Characterization of highly efficient heavy-ion mutagenesis in Arabidopsis thaliana. BMC Plant Biology, 11, 161(2011).

[16] L M M Spencer, B P Forster. Manual on mutation breeding(2018).

[17] Fu YANG, Jingpeng LI, Lixia YU et al. Reflections on the method of northern japonica rice breeding using high energy heavy ion beam radiation. China Rice, 29, 72-75(2023).

[18] Guanren XU. Plant mutation breeding(1996).

[19] Ye SHAO, Yan PENG, Bigang MAO et al. M1TDS technology and creation of low-cadmium accumulation parents for hybrid rice breeding. Hybrid Rice, 37, 1-11(2022).

[20] M Szurman-Zubrzycka, M Kurowska, B J Till et al. Is it the end of TILLING era in plant science?. Frontiers in Plant Science, 14, 1160695(2023).

[21] N Durut, O Mittelsten Scheid. The role of noncoding RNAs in double-strand break repair. Frontiers in Plant Science, 10, 1155(2019).

[22] W Ren, H Wang, Y Du et al. Multi-generation study of heavy ion beam-induced mutations and agronomic trait variations to accelerate rice breeding. Frontiers in Plant Science, 14, 1213807(2023).

[23] G L Yang, W L Luo, J Zhang et al. Genome-wide comparisons of mutations induced by carbon-ion beam and gamma-rays irradiation in rice via resequencing multiple mutants. Frontiers in Plant Science, 10, 1514(2019).

[24] J Zhang, Z A Peng, Q L Liu et al. Time course analysis of genome-wide identification of mutations induced by and genes expressed in response to carbon ion beam irradiation in rice (Oryza sativa L.). Genes, 12, 1391(2021).

[25] Y Kazama, K Ishii, T Hirano et al. Different mutational function of low- and high-linear energy transfer heavy-ion irradiation demonstrated by whole-genome resequencing of Arabidopsis mutants. The Plant Journal: for Cell and Molecular Biology, 92, 1020-1030(2017).

[26] Y C Zheng, S Li, J Z Huang et al. Identification and characterization of inheritable structural variations induced by ion beam radiations in rice. Mutation Research, 823, 111757(2021).

[27] F Li, A Shimizu, T Nishio et al. Comparison and characterization of mutations induced by gamma-ray and carbon-ion irradiation in rice (Oryza sativa L.) using whole-genome resequencing. G3, 9, 3743-3751(2019).

[28] Y Oono, H Ichida, R Morita et al. Genome sequencing of ion-beam-induced mutants facilitates detection of candidate genes responsible for phenotypes of mutants in rice. Mutation Research, 821, 111691(2020).

[29] H Ichida, R Morita, Y Shirakawa et al. Targeted exome sequencing of unselected heavy-ion beam-irradiated populations reveals less-biased mutation characteristics in the rice genome. The Plant Journal: for Cell and Molecular Biology, 98, 301-314(2019).

[30] B Phanchaisri, N Samsang, L D Yu et al. Expression of OsSPY and 14-3-3 genes involved in plant height variations of ion-beam-induced KDML 105 rice mutants. Mutation Research, 734, 56-61(2012).

[31] Minjuan ZHANG, Shuaijun LI, Qiongqiong CHEN et al. Genetic mapping and proteomic analysis of the dwarf and low-tillering mutant dlt3 in rice. Chinese Journal of Rice Science, 32, 529-537(2018).

[32] S Yadav, U M Singh, S M Naik et al. Molecular mapping of QTLs associated with lodging resistance in dry direct-seeded rice (Oryza sativaL.). Frontiers in Plant Science, 8, 1431(2017).

[33] Q Qian, Y H Li, D L Zeng et al. Isolation and genetic characterization of a fragile plant mutant in rice (Oryza sauva L.). Chinese Science Bulletin, 46, 2082-2085(2001).

[34] H R Jiang, Y Ren, J Y Guo et al. CEF3 is involved in membrane trafficking and essential for secondary cell wall biosynthesis and its mutation enhanced biomass enzymatic saccharification in rice. Biotechnology for Biofuels and Bioproducts, 15, 111(2022).

[35] Haipai JIANG, Shuying ZHANG, Jinsong BAO et al. Genetic analysis and mapping of high-tillering and dwarf mutant htd1-2 in rice. Hereditas (Beijing), 31, 531-539(2009).

[36] D Jiang, J J Fang, L M Lou et al. Characterization of a null allelic mutant of the rice NAL1 gene reveals its role in regulating cell division. PLoS One, 10, e0118169(2015).

[37] Changjie YAN, Song YAN, Zhengqiu ZHANG et al. Genetic analysis and gene mapping of a new rice leaf-rolling mutant rl9(t). Chinese Science Bulletin, 50, 2757-2762(2005).

[38] Jingxin ZHANG, Dayuan SUN, Qiyun YANG et al. Preliminary report on the rice blast resistance of space-induced mutants derived from rice cultivar“Taihang-68. Journal of Nuclear Agricultural Sciences, 26, 734-739(2012).

[39] Wei ZANG, Shuyuan ZHANG, Guomin ZHANG et al. Screening of resistant mutant induced by γ-rays irradiation to rice blast. Journal of Nuclear Agricultural Sciences, 22, 248-252(2008).

[40] Jianjun WANG, Xudong ZHU, Linyou WANG et al. Disease resistance and cytological analyses on lesion resembling disease mutant lrd40 in Oryza sativa. Chinese Journal of Rice Science, 19, 111-116(2005).

[41] S Ishikawa, Y Ishimaru, M Igura et al. Ion-beam irradiation, gene identification, and marker-assisted breeding in the development of low-cadmium rice. PNAS, 109, 19166-19171(2012).

[42] Yuanyuan LIN, Huiru CHEN, Binmei LIU et al. Study on low-cadmium rice mutants induced by 12C6+ ion beam. Nuclear Physics Review, 33, 488-493(2016).

[43] Q M Lyu, W G Li, Z Z Sun et al. Resequencing of 1, 143 indica rice accessions reveals important genetic variations and different heterosis patterns. Nature Communications, 11, 4778(2020).

[44] R Morita, M Nakagawa, H Takehisa et al. Heavy-ion beam mutagenesis identified an essential gene for chloroplast development under cold stress conditions during both early growth and tillering stages in rice. Bioscience, Biotechnology, and Biochemistry, 81, 271-282(2017).

[45] Q Jiang, J Mei, X D Gong et al. Importance of the rice TCD9 encoding α subunit of chaperonin protein 60 (Cpn60α) for the chloroplast development during the early leaf stage. Plant Science: an International Journal of Experimental Plant Biology, 215/216, 172-179(2014).

[46] A de Andrade, A Tulmann-Neto, F A Tcacenco et al. Development of rice (Oryza sativa) lines resistant to aryloxyphenoxypropionate herbicides through induced mutation with gamma rays. Plant Breeding, 137, 364-369(2018).

[47] Y Ren, B M Liu, H R Jiang et al. Precision editing of GLR1 confers glufosinate resistance without yield penalty in rice. Plant Biotechnology Journal, 21, 2417-2419(2023).

[48] J S Bao, B W Deng, L Zhang. Molecular and genetic bases of rice cooking and eating quality: an updated review. Cereal Chemistry, 100, 1220-1233(2023).

[49] Weimin CHENG, Binmei LIU, Yafeng YE et al. Establishment of rice amylose and protein mutant lines by heavy ion irradiation. Chinese Agricultural Science Bulletin, 32, 86-90(2016).

[50] Tao GUO, Xuan WEI, Hui WANG et al. Genetic analysis of low amylose content trait in two oryza indica mutants. Journal of South China Agricultural University, 30, 10-13(2009).

[51] Qingyao SHU, Xiaofei CHI, Shanfu CHEN et al. Development of a low gelatinization temperature mutant(Mgt-1) of rice and its grain quality characters. Journal of Nuclear Agricultural Sciences, 15, 341-344(2001).

[53] A Tanaka, N Shikazono, Y Hase. Studies on biological effects of ion beams on lethality, molecular nature of mutation, mutation rate, and spectrum of mutation phenotype for mutation breeding in higher plants. Journal of Radiation Research, 51, 223-233(2010).