面向高产高效杂交水稻制种的育种策略与应用

doi:10.3969/j.issn.1006-8082.2026.03.004

摘要/Abstract

摘要：

杂交水稻的成功应用为保障我国粮食安全作出了巨大贡献，而高效制种技术是其大规模推广的关键。本文系统回顾了我国杂交水稻制种技术的发展历程，从初期的探索与完善到现今的成熟与高产，并重点探讨了实现高产高效制种的育种策略。综述了通过提高母本柱头外露率与活力、精准调控父母本花期相遇以及增强亲本耐高温能力等关键技术以提升异交结实率的研究进展。分析了包括叶色与颖壳颜色标记、抗除草剂技术及机械化混播混收在内的新型除杂与制种技术，这些技术显著提升了种子纯度与生产效率，降低了人工成本。最后，展望了未来杂交水稻制种的发展方向，指出创制适合全程机械化的亲本新材料，以及利用无融合生殖固定杂种优势，将是实现杂交水稻生产可持续发展的根本路径。

关键词: 杂交水稻, 制种技术, 育种策略, 高产高效, 机械化

Abstract:

The successful application of hybrid rice has contributed significantly to ensuring China’s food security, with efficient seed production technology being crucial for its large-scale promotion. This paper systematically reviews the development process of hybrid rice seed production technology in China, from the initial exploration and improvement stages to the current phase of maturity and high yield, with a focus on breeding strategies for achieving high-yield and high-efficiency seed production. It summarizes research advances in key technologies such as improving the stigma excretion rate and vitality of the female parent, precisely synchronizing the flowering time of parental lines, and enhancing parental heat tolerance to increase outcrossing seed set rates. The paper also analyzes novel seed purification and production technologies, including leaf and hull color markers, herbicide-resistant techniques, and mechanized mixed planting and harvesting, which have significantly improved seed purity, production efficiency, and reduced labor costs. Finally, the paper prospects future development directions for hybrid rice seed production, pointing out that creating new parental lines suitable for whole-process mechanization and utilizing apomixis to fix heterosis will be fundamental paths toward achieving sustainable development in hybrid rice production.

Key words: hybrid rice, seed production technology, breeding strategy, high yield and efficiency, mechanization

中图分类号:

S511.032

彭佳旗, 李彦, 孙平勇, 张武汉, 舒服, 赵旺辉, 吕启明, 李元杰, 邓华凤, 雷东阳, 何强. 面向高产高效杂交水稻制种的育种策略与应用[J]. 中国稻米, 2026, 32(3): 16-22.

PENG Jiaqi, LI Yan, SUN Pingyong, ZHANG Wuhan, SHU Fu, ZHAO Wanghui, LV Qiming, LI Yuanjie, DENG Huafeng, LEI Dongyang, HE Qiang. Breeding Strategies and Application for High-Yield and High-Efficiency Hybrid Rice Seed Production[J]. China Rice, 2026, 32(3): 16-22.

参考文献 69

[1]	袁隆平. 中国杂交水稻的研究与发展[J]. 科技导报, 2016, 34(20):64-65.
[2]	卢庆善. 农作物杂种优势[M]. 北京: 中国农业科学技术出版社, 2001:56-57.
[3]	袁隆平. 水稻的雄性不孕性[J]. 科学通报, 1966, 11(4):185-188.
[4]	祝平, 刘孙旺, 管庆容. 杂交水稻制种技术研究[J]. 现代农业科学, 2009, 16(7):46-47.
[5]	何强, 邓华凤, 孙平勇, 等. 杂交水稻[J]. Engineering, 2020, 6(9):967-981.
[6]	袁隆平. 中国的杂交水稻[J]. 杂交水稻, 1986, 1(1):5-10.
[7]	许世觉. 中国杂交水稻制种技术的发展[J]. 杂交水稻, 1994, 9(suppl1):50-51.
[8]	雷东阳, 陈立云. 我国杂交水稻制种的回顾与展望[J]. 作物研究, 2006, 20(5):367-370.
[9]	孙平勇, 舒服, 邓华凤. 杂交水稻制种大面积单产创新高[J]. 杂交水稻, 2022, 37(6):139.
[10]	孙平勇, 舒服, 李天春, 等. 优质两系杂交水稻爽两优132高产制种技术[J]. 中国稻米, 2023, 29(6):114-115.
[11]	田书军, 张城, 张雪, 等. 水稻柱头外露性状遗传研究进展[J]. 辽宁农业科学, 2024, 59(3):53-56.
[12]	袁隆平. 杂交水稻学[M]. 北京: 中国农业出版社, 2002:37-40.
[13]	李陶, 陈一吾. 水稻柱头外露率的遗传研究[J]. 作物学报, 1987, 13(4):314-321.
[14]	岳高红, 潘彬荣, 许立奎, 等. 水稻柱头外露率的研究进展[J]. 种子, 2009, 28(1):47-50.
[15]	周国华, 李铮友, 李本逊, 等. 优质滇型杂交粳稻新组合滇杂86的选育[J]. 杂交水稻, 2010, 25(5):22-24.
[16]	李明寿, 刘毅, 杨学龙, 等. 节水抗旱水稻不育系沪旱1A柱头外露率的改良研究[J]. 杂交水稻, 2016, 31(4):17-20.
[17]	李晨, 孙传清, 穆平, 等. 栽培稻与普遍野生稻两个重要分类性状花药长度和柱头外露率的QTL分析[J]. 遗传学报, 2001, 28(8):746-751.
[18]	尹成, 李平波, 高冠军, 等. 水稻柱头外露率QTL定位[J]. 分子植物育种, 2014, 12(1):43-49.
[19]	MIYATA M, YAMAMOTO T, KOMORI T, et al. Marker-assisted selection and evaluation of the QTL for stigma exsertion under japonica rice genetic background[J]. Theoretical and Applied Genetics, 2007, 114(3):539-548.
[20]	ZHU X Y, GOU Y J, HENG Y Q, et al. Targeted manipulation of grain shape genes effectively improves outcrossing rate and hybrid seed production in rice[J]. Plant Biotechnology Journal, 2023, 21(2):381-390.
[21]	袁隆平. 杂交水稻培育的实践和理论[J]. 中国农业科学, 1977, 10(1):27-31.
[22]	WANG M M, ZHU X P, PENG G Q, et al. Methylesterification of cell-wall pectin controls the diurnal flower-opening times in rice[J]. Molecular Plant, 2022, 15(6):956-972.
[23]	WANG M M, ZHU X P, HUANG Z, et al. Controlling diurnal flower-opening time by manipulating the jasmonate pathway accelerates development of indica-japonica hybrid rice breeding[J]. Plant Biotechnology Journal, 2024, 22(8):2 267-2 281.
[24]	ZHU X P, WANG M M, HUANG Z, et al. The OsMYC₂-JA feedback loop regulates diurnal flower-opening time via cell wall loosening in rice[J]. The Plant Journal, 2024, 119(6):2 585-2 598.
[25]	XU P Z, WU T K, ALI A, et al. EARLY MORNING FLOWERING1 (EMF1) regulates the floret opening time by mediating lodicule cell wall formation in rice[J]. Plant Biotechnology Journal, 2022, 20(8):1 441-1 443.
[26]	GOU Y J, HENG Y Q, DING W Y, et al. Natural variation in OsMYB8 confers diurnal floret opening time divergence between indica and japonica subspecies[J]. Nature Communications, 2024, 15:2 262.
[27]	刘刚, 夏快飞, 吴艳, 等. 水稻耐热新种质R203的创制与应用[J]. 中国农业科学, 2023, 56(3):405-415.
[28]	卢德文, 曾博虹, 赵佳梁, 等. 优质耐热香型恢复系郁香占的选育及应用[J]. 中国种业, 2024, 43(9):105-107.
[29]	王伍梅, 王辉, 杜士云. 水稻耐热性评价方法研究进展[J]. 安徽农业科学, 2021, 49(10):20-27.
[30]	陈劲, 唐文帮. 水稻耐极端高温育种研究进展[J]. 杂交水稻, 2024, 39(3):1-11.
[31]	钦鹏, 樊世军, 高鹏, 等. 水稻耐高温相关基因功能及其信号通路研究进展[J]. 四川农业大学学报, 2021, 39(3):279-285.
[32]	LI X M, CHAO D Y, WU Y, et al. Natural alleles of a proteasome α2 subunit gene contribute to thermotolerance and adaptation of African rice[J]. Nature Genetics, 2015, 47(7):827-833.
[33]	XU Y F, ZHANG L, OU S J, et al. Natural variations of SLG1 confer high-temperature tolerance in indica rice[J]. Nature Communications, 2020, 11:5 441.
[34]	CAO Z B, TANG H W, CAI Y H, et al. Natural variation of HTH5 from wild rice, Oryza rufipogon Griff., is involved in conferring high-temperature tolerance at the heading stage[J]. Plant Biotechnology Journal, 2022, 20(8):1 591-1 605.
[35]	陈斌. 杂交水稻制种田杂株类型、特征及去杂[J]. 福建农业, 2004, 11(6):9.
[36]	龚太伦, 李顺武, 鲁远源, 等. 杂交水稻种子质量控制技术[J]. 中国种业, 2015, 34(8):91-93.
[37]	黄陆军. 杂交水稻制种田间除杂的几种方法[J]. 种子世界, 1986, 4(10):29.
[38]	陆传萍. 杂交水稻制种田间杂株识别技术[J]. 杂交水稻, 2004, 19(1):42.
[39]	董凤高, 朱旭东, 熊振民, 等. 以淡绿叶为标记的籼型光—温敏核不育系M2S的选育[J]. 中国水稻科学, 1995, 9(2):65-70.
[40]	曹立勇, 钱前, 朱旭东, 等. 紫叶标记籼型光-温敏核不育系中紫S的选育及其配组的杂种优势[J]. 作物学报, 1999, 25(1):44-49.
[41]	赵海军, 吴殿星, 舒庆尧, 等. 携带白化转绿型叶色标记光温敏核不育系玉兔S的选育及其特征特性[J]. 中国水稻科学, 2004, 18(6):41-47.
[42]	沈圣泉, 舒庆尧, 吴殿星, 等. 白化转绿型水稻三系不育系白丰A的选育[J]. 杂交水稻, 2005, 20(5):10-11.
[43]	张从合, 陈金节, 蒋家月, 等. 带浅褐色稃壳标记的籼型水稻光温敏核不育系新安S的选育[J]. 杂交水稻, 2007, 22(4):4-6.
[44]	许可, 袁定阳, 谭炎宁, 等. 适于混播制种的水稻隐性红颖资源RG-1的发现及其特征特性研究[J]. 杂交水稻, 2018, 33(4):17-21.
[45]	肖国樱. 作物对除草剂的抗性及其在杂种优势利用中应用策略的探讨[J]. 杂交水稻, 1997, 12(5):4-6.
[46]	黄大年, 李敬阳, 章善庆, 等. 用抗除草剂基因快速检测和提高杂交稻纯度的新技术[J]. 科学通报, 1998, 43(1):67-70.
[47]	张集文, 武晓智. 苯达松致死标记两用不育系8077S的选育及其应用[J]. 杂交水稻, 2000, 15(6):7-10.
[48]	刘爱民, 廖翠猛, 杨文星. 杂交水稻种子生产面临的问题与技术创新[J]. 杂交水稻, 2010, 25(suppl1):459-461.
[49]	王跃星, 葛露方, 朱旭东. 杂交水稻机械化制种技术研究的现状与展望[J]. 杂交水稻, 2011, 26(4):5-7.
[50]	唐文帮, 陈晓军, 张桂莲, 等. 杂交水稻机械化制种现状与技术突破[J]. 中国稻米, 2022, 28(5):20-27.
[51]	刘爱民, 唐文帮. 杂交水稻种子生产加工机械化技术的进步与发展[J]. 中国稻米, 2025, 31(4):71-78.
[52]	刘延斌, 杨远柱, 刘建丰, 等. 杂交水稻亲本混播机械化制种研究进展[J]. 作物研究, 2012, 26(1):85-87.
[53]	何立斌, 曹立勇, 钱前, 等. 稻壳颜色标记在杂交水稻制种中的应用初探[J]. 浙江农业学报, 2001, 13(6):33-36.
[54]	张志雄, 张志勇, 向跃武, 等. 具橙红色颖壳标记性状的优质香稻不育系花香A的选育与利用[J]. 杂交水稻, 2009, 24(6):15-16.
[55]	吕直文, 郑济万, 卿明敬, 等. 杂交水稻理想型机械化制种组合Ⅱ优86[J]. 杂交水稻, 1996, 11(5):14-15.
[56]	雷斌, 张桂莲, 邓化冰, 等. 水稻小粒型两系不育系卓201S的选育与利用[J]. 杂交水稻, 2020, 35(2):6-9.
[57]	周杰强, 张桂莲, 邓化冰, 等. 水稻小粒不育系新组合卓两优141混播制种优势分析[J]. 作物学报, 2022, 48(2):320-331.
[58]	刘慧敏, 周杰强, 胡远艺, 等. 水稻小粒不育系新组合卓两优1126的高产特征[J]. 中国水稻科学, 2024, 38(2):160-171.
[59]	夏玉梅, 唐宁, 詹祎捷, 等. 杂交水稻混播机械化制种技术研究进展[J]. 杂交水稻, 2020, 35(2):1-5.
[60]	XIA Y M, TANG N, HU Y Y, et al. A method for mechanized hybrid rice seed production using female sterile rice[J]. Rice, 2019, 12(1):39.
[61]	LI W, GUO X Q, WU W B, et al. Construction of a novel female sterility system for hybrid rice[J]. Frontiers in Plant Science, 2022, 12:815 401.
[62]	何强, 邓华凤, 李红玲, 等. 一种具有白色颖花标记性状水稻两用核不育系的选育方法:202310014102.8[P]. 2024-02-09.
[63]	袁隆平. 杂交水稻的育种战略设想[J]. 杂交水稻, 1987, 2(1):1-3.
[64]	KHANDAY I, SKINNER D, YANG B, et al. A male-expressed rice embryogenic trigger redirected for asexual propagation through seeds[J]. Nature, 2019, 565(7737):91-95.
[65]	WANG C, LIU Q, SHEN Y, et al. Clonal seeds from hybrid rice by simultaneous genome engineering of meiosis and fertilization genes[J]. Nature Biotechnology, 2019, 37(3):283-286.
[66]	WEI X, LIU C L, CHEN X, et al. Synthetic apomixis with normal hybrid rice seed production[J]. Molecular Plant, 2023, 16(3):489-492.
[67]	HUANG Y, MENG X B, RAO Y C, et al. OsWUS-driven synthetic apomixis in hybrid rice[J]. Plant Communications, 2025, 6(1):101 136.
[68]	HU F Y, LIU C L, JIN X C, et al. OsPLDα2-dependent synthetic apomixis enables normal seed setting in hybrid rice via genome editing[J]. Science Bulletin, 2025. doi: 10.1016/j.scib.2025.05.022
[69]	ZHAN Y J, XIA Y M, WANG Y, et al. Efficient clonal seeds sorting for apomictic hybrid rice using a pollen-specific gene switch system[J]. Plant Biotechnology Journal, 2025, 23(6):2 266-2 275.