四倍体‘胡柚’与4个柚品种倍性杂交创制柑橘三倍体

doi:10.3864/j.issn.0578-1752.2026.10.016

中国农业科学 ›› 2026, Vol. 59 ›› Issue (10): 2288-2298.doi: 10.3864/j.issn.0578-1752.2026.10.016

• 研究简报 • 上一篇

四倍体‘胡柚’与4个柚品种倍性杂交创制柑橘三倍体

沈尚洁¹(), 陈卉¹(), 周宏剑², 洪雅妍³, 叶哲希², 胡智勇², 吴金洁², 王刚⁴, 郑利珍⁵, 张林⁶, 张敏²(), 张迟¹()

¹ 浙江农林大学园艺学院/农业农村部亚热带果品蔬菜质量安全控制重点实验室，杭州 311300
² 浙江农林大学/森林食物资源挖掘与利用全国重点实验室，杭州 311300
³ 常山县何家乡人民政府，浙江常山 324200
⁴ 常山县农业农村局，浙江常山 324200
⁵ 衢州市柯城区农业农村局，浙江衢州 324000
⁶ 浙江省农业技术推广中心，杭州 310020

收稿日期:2026-01-04 接受日期:2026-03-02 出版日期:2026-05-16 发布日期:2026-05-20
通信作者:
张敏，E-mail：mzhang@zafu.edu.cn。
张迟，E-mail：zhangchi1978@zafu.edu.cn。
联系方式: 沈尚洁，E-mail：sjshen@stu.zafu.edu.cn。陈卉，E-mail：chenhui5148@163.com。沈尚洁和陈卉为同等贡献作者。
基金资助:
浙江省农业重大技术协同推广计划(2024ZDXT04); 衢州市柯城区柑橘品质改良提升示范基地项目(ZJZX2023021); 衢州市柯城区柑橘产业科技攻关项目([2022]22-3)

Innovation of Citrus Triploids by Ploidy Hybridization Between Tetraploid Huyou and Four Pomelo Cultivars

SHEN ShangJie¹(), CHEN Hui¹(), ZHOU HongJian², HONG YaYan³, YE ZheXi², HU ZhiYong², WU JinJie², WANG Gang⁴, ZHENG LiZhen⁵, ZHANG Lin⁶, ZHANG Min²(), ZHANG Chi¹()

¹ School of Horticulture, Zhejiang A&F University/Key Laboratory of Quality and Safety Control for Subtropical Fruit and Vegetable, Ministry of Agriculture and Rural Affairs, Hangzhou 311300
² Zhejiang A&F University/State Key Laboratory of Forest Food Resources Development and Utilization, Hangzhou 311300
³ The People’s Government of Hejia Town, Changshan 324200, Zhejiang
⁴ Agriculture and Rural Bureau of Changshan County, Changshan 324200, Zhejiang
⁵ Bureau of Agriculture and Rural Affairs of Kecheng District, Quzhou 324000, Zhejiang
⁶ Zhejiang Agricultural Technology Extension Center, Hangzhou 310020

Received:2026-01-04 Accepted:2026-03-02 Published:2026-05-16 Online:2026-05-20

摘要/Abstract

摘要：

【目的】通过四倍体与二倍体杂交创制柑橘三倍体新种质，为选育无核柚奠定种质基础。【方法】以四倍体‘胡柚’为母本，二倍体‘琯溪蜜柚’‘早香柚’‘东试早柚’‘红宝石柚’为父本，配置4个杂交组合进行人工授粉。果实成熟后采收并获取种子，根据种子大小分类接种于MT培养基进行组织培养以获得再生植株。采用流式细胞仪对再生植株进行倍性鉴定，并利用SSR分子标记对三倍体后代进行遗传鉴定。对三倍体后代的生长势、叶片形态、单多胚性分离规律等进行系统分析。【结果】4个杂交组合共授粉97朵花，坐果29个，平均坐果率为29.90%，不同父本组合的坐果率存在差异，其中，以‘红宝石柚’为父本的组合坐果率最高（57.14%），‘东试早柚’组合最低（9.09%）。共获得种子526粒，经组织培养获得再生植株303株，平均植株再生率为57.60%。流式细胞仪倍性分析结果显示，共获得三倍体植株66株。不同大小种子均能再生出三倍体，其中，以小种子的三倍体发生率最高（86.36%）。三倍体后代在株高、叶形等性状上表现出丰富的遗传变异，部分组合子代株高显著高于母本。四倍体‘胡柚’×‘红宝石柚’组合的三倍体子代翼叶长宽比介于双亲之间，其余组合子代翼叶长宽比与母本无显著差异。利用5对SSR引物对66株三倍体后代进行遗传鉴定，所有植株均扩增出双亲的特异条带，证实其为双亲杂交所得。其中，引物Ma3-96在四倍体‘胡柚’×‘琯溪蜜柚’组合的后代中扩增出5种带型，经卡方检验符合双二倍体（4﹕1﹕1﹕5﹕1）的理论遗传分离比例。单多胚性状分子标记鉴定结果表明，母本四倍体‘胡柚’为多胚类型，4个二倍体父本均为单胚类型。在66株三倍体后代中，56株表现为多胚，10株表现为单胚。四倍体‘胡柚’×‘琯溪蜜柚’组合后代的单多胚分离比（5﹕35）经卡方检验符合理论预期（1﹕5），表明该组合中单多胚性状的遗传遵循孟德尔分离规律。【结论】成功创制了一批异源三倍体柑橘新种质。

关键词: 柚, 胡柚, 三倍体, 流式细胞仪, SSR分子标记

Abstract:

【Objective】Pummelo (Citrus grandis) is seedy under pollination to maintain fruit set and fruit quality. The objective of this study is to develop novel triploid citrus germplasm by 4x×2x intreploid hybridization, thereby providing a germplasm foundation for the breeding of seedless pummelo varieties.【Method】Allotriploids were obtained from four combinations of interploidy hybridization sharing a tetraploid Changshan Huyou (C. changshan-huyou) as their common female parent and having C. grandis Guanximiyou, C. grandis Zaoxiangyou, C. grandis Dongshizaoyou, and C. grandis Hongbaoshiyou as the male parent, respectively. Upon fruit maturity, seeds were harvested and categorized based on their sizes for inoculation on MT medium for tissue culture to obtain regenerated plants. Ploidy analysis of regenerated plants was conducted using flow cytometry, and genetic identification of triploid progenies was performed using SSR molecular markers. Additionally, systematic analysis was conducted on growth vigor, leaf morphology, and segregation patterns of monoembryony/polyembryony in triploid progenies.【Result】A total of 97 flowers were pollinated across the four hybrid combinations, yielding 29 fruits with an average fruit set rate of 29.90%. Variation in fruit set rate was observed among different male parent combinations, and the combination using Hongbaoshiyou as the male parent exhibited the highest fruit set rate (57.14%), whereas the Dongshizaoyou combination showed the lowest (9.09%). A total of 526 seeds were harvested, from which 303 regenerated plants were produced through tissue culture, resulting in an average plant regeneration rate of 57.60%. A total of 66 triploid plants were revealed by analysis of flow cytometry. These triploids were regenerated from seeds of various sizes, with the highest incidence of triploids observed in small seeds (86.36%). Triploid progenies displayed rich genetic variation in traits such as plant height and leaf morphology. In some combinations, the height of progenies was significantly greater than the female parent. The wing leaf length-to-width ratio of triploid progenies from the tetraploid Huyou×Hongbaoshiyou combination was intermediate between both parents, while in other combinations, the wing leaf length-to-width ratio of the progenies showed no significant difference from that of the female parent. Genetic identification of the 66 triploid progenies using five pairs of SSR primers showed that all triploids amplified specific bands from both parents, confirming their hybrid origin. Specifically, primer Ma3-96 amplified five types of bands in progenies from the combination of the tetraploid Huyou×Guanximiyou, and the observed ratio of these types was in accordance with the theoretical segregation ratio (4:1:1:5:1) expected for a double diploid upon chi-square test. Molecular marker identification of monoembryony/polyembryony traits indicated that the female parent, tetraploid Huyou, was polyembryonic, while the four diploid male parents were all monoembryonic. Among the 66 triploid progenies, 56 exhibited polyembryony and 10 exhibited monoembryony. The segregation ratio of monoembryony to polyembryony (5:35) in the progenies from the combination of tetraploid Huyou×Guanximiyou conformed to the theoretical expectation (1:5) upon chi-square test, indicating that the inheritance of the monoembryony/polyembryony trait in this combination followed Mendelian segregation patterns.【Conclusion】A batch of novel allotriploid germplasm was successfully generated, providing valuable genetic resources for breeding of new seedless pummelo varieties.

Key words: Citrus grandis, Citrus changshan-huyou, allotriploid, flow cytometry, SSR markers

沈尚洁, 陈卉, 周宏剑, 洪雅妍, 叶哲希, 胡智勇, 吴金洁, 王刚, 郑利珍, 张林, 张敏, 张迟. 四倍体‘胡柚’与4个柚品种倍性杂交创制柑橘三倍体[J]. 中国农业科学, 2026, 59(10): 2288-2298.

SHEN ShangJie, CHEN Hui, ZHOU HongJian, HONG YaYan, YE ZheXi, HU ZhiYong, WU JinJie, WANG Gang, ZHENG LiZhen, ZHANG Lin, ZHANG Min, ZHANG Chi. Innovation of Citrus Triploids by Ploidy Hybridization Between Tetraploid Huyou and Four Pomelo Cultivars[J]. Scientia Agricultura Sinica, 2026, 59(10): 2288-2298.

图/表 9

表1

表2

图1

图2

表3

图3

图4

图5

图6

参考文献 36

[1]	陈璞, 徐振江, 江东, 易静, 苏穆清, 邓超, 饶得花. 柚类种质资源DUS测试数量性状分级研究. 果树学报, 2024, 41(9): 1885-1902.
	CHEN P, XU Z J, JIANG D, YI J, SU M Q, DENG C, RAO D H. Classification study on quantitative characteristics of pomelo germplasm resources for DUS test. Journal of Fruit Science, 2024, 41(9): 1885-1902. (in Chinese)
[2]	汪妮娜, 廖惠红, 黄宏明, 王茜, 刘福平, 黄其椿, 陈香玲. 琯溪蜜柚汁胞粒化影响因素及防控技术综述. 广西农学报, 2019, 34(4): 60-64.
	WANG N N, LIAO H H, HUANG H M, WANG Q, LIU F P, HUANG Q C, CHEN X L. Review on influencing factors and prevention & control techniques of cellular granulation of Guanxi honey pomelo juice. Journal of Guangxi Agriculture, 2019, 34(4): 60-64. (in Chinese)
[3]	陈秋夏, 郑坚, 张旭乐, 徐文荣. 永嘉早香柚果实裂瓣规律与授粉调控. 果树学报, 2007, 24(1): 68-71.
	CHEN Q X, ZHENG J, ZHANG X L, XU W R. Study on the effect of hand pollination on juice sac cracking of Yongjia Zaoxiangyou pomelo cultivar. Journal of Fruit Science, 2007, 24(1): 68-71. (in Chinese)
[4]	徐祥增, 邓乐晔, 张小娇, 张彩虹, 万子龙, 高世德. 不同品种授粉对东试早柚果实贮藏品质的影响. 中国南方果树, 2025: 1-15.
	XU X Z, DENG Y Y, ZHANG X J, ZHANG C H, WAN Z L, GAO S D. Effects of different pollination cultivars on storage quality of Dongshizao pummelo fruit. South China Fruits, 2025: 1-15. (in Chinese)
[5]	张瑞敏, 吴平治, 樊正炎, 朱从一, 黄永敬, 张曼, 曾继吾. 不同授粉品种对沙田柚果实品质的影响. 现代食品, 2023, 29(21): 193-196.
	ZHANG R M, WU P Z, FAN Z Y, ZHU C Y, HUANG Y J, ZHANG M, ZENG J W. Effects of different pollination varieties on fruit quality of Shatian pomelo. Modern Food, 2023, 29(21): 193-196. (in Chinese)
[6]	NAVARRO L, ALEZA P, CUENCA J, JUÁREZ J, PINA J A, ORTEGA C, NAVARRO A, ORTEGA V. The mandarin triploid breeding program in Spain. Acta Horticulturae, 2015(1065): 389-395.
[7]	OLLITRAULT P, DAMBIER D, LURO F, FROELICHER Y. Ploidy manipulation for breeding seedless triploid citrus. Plant Breeding Reviews, 2008, 30: 323-352.
[8]	解凯东, 彭珺, 袁东亚, 强瑞瑞, 谢善鹏, 周锐, 夏强明, 伍小萌, 柯甫志, 刘高平, 等. 以本地早橘和槾橘为母本倍性杂交创制柑橘三倍体. 中国农业科学, 2020, 53(23): 4961-4968. doi: 10.3864/j.issn.0578-1752.2020.23.020.
	XIE K D, PENG J, YUAN D Y, QIANG R R, XIE S P, ZHOU R, XIA Q M, WU X M, KE F Z, LIU G P, et al. Production of Citrus triploids based on interploidy crossing with bendizao and man tangerines as female parents. Scientia Agricultura Sinica, 2020, 53(23): 4961-4968. doi: 10.3864/j.issn.0578-1752.2020.23.020. (in Chinese)
[9]	刘承浪, 冯迪, 曹宗洪, 陶亚文, 徐祥增, 高世德, 岳建强, 谢宗周, 叶俊丽, 柴利军, 等. 以东试早柚为母本创制柑橘三倍体种质资源. 果树学报, 2023, 40(10): 2041-2049.
	LIU C L, FENG D, CAO Z H, TAO Y W, XU X Z, GAO S D, YUE J Q, XIE Z Z, YE J L, CHAI L J, et al. Creation of triploid seedling plants of Citrus by crossing Dongshizao pummelo female with tetraploid male parents. Journal of Fruit Science, 2023, 40(10): 2041-2049. (in Chinese)
[10]	VILORIA Z, GROSSER J W. Acid Citrus fruit improvement via interploid hybridization using allotetraploid somatic hybrid and autotetraploid breeding parents. Journal of the American Society for Horticultural Science, 2005, 130(3): 392-402. doi: 10.21273/JASHS.130.3.392
[11]	陈方永, 倪海枝, 赵凯, 任正初. 柚新品种‘浙玉1号’. 园艺学报, 2009, 36(9): 1400.
	CHEN F Y, NI H Z, ZHAO K, REN Z C. A new pomelo cultivar ‘Zheyu 1’. Acta Horticulturae Sinica, 2009, 36(9): 1400. (in Chinese)
[12]	ALEZA P, JUÁREZ J, HERNÁNDEZ M, OLLITRAULT P, NAVARRO L. Implementation of extensive Citrus triploid breeding programs based on 4x×2x sexual hybridisations. Tree Genetics & Genomes, 2012, 8(6): 1293-1306.
[13]	施灵荣, 赵四清, 方修贵. 常山胡柚产业现状及开发前景. 浙江柑橘, 2017, 34(3): 2-5.
	SHI L R, ZHAO S Q, FANG X G. Present situation and development prospect of Changshan Huyou industry. Zhejiang Ganju, 2017, 34(3): 2-5. (in Chinese)
[14]	HUANG P R, XU T Y, WANG G, ZHANG L, YAO Y, ZHANG M, ZHANG C. Morphological and metabolic changes in Changshan Huyou (Citrus Changshan-Huyou) following natural tetraploidization. BMC Plant Biology, 2025, 25(1): 301. doi: 10.1186/s12870-025-06293-4
[15]	徐天予, 张迟, 王刚, 叶潇玲, 陈翔, 叶生月, 张小琴, 张敏. 四倍体胡柚与鸡尾葡萄柚有性杂交创制三倍体新种质. 果树学报, 2025, 42(1): 63-71.
	XU T Y, ZHANG C, WANG G, YE X L, CHEN X, YE S Y, ZHANG X Q, ZHANG M. Regeneration of triploid Citrus germplasm by the crossing between Tetra-ploid Huyou and Cocktail grapefruit. Journal of Fruit Science, 2025, 42(1): 63-71. (in Chinese)
[16]	王福生, 江东. 应用cpSSR和EST-SSR标记进行柑橘特异种质资源遗传背景研究. 园艺学报, 2010, 37(3): 465-474.
	WANG F S, JIANG D. Studies on genetic background of important germplasm resources among Citrus based on cpSSR and EST-SSR marker. Acta Horticulturae Sinica, 2010, 37(3): 465-474. (in Chinese)
[17]	梁武军, 解凯东, 郭大勇, 谢宗周, 徐强, 伊华林, 郭文武. 柑橘10个品种实生后代多倍体的发掘及SSR鉴定. 园艺学报, 2014, 41(3): 409-416.
	LIANG W J, XIE K D, GUO D Y, XIE Z Z, XU Q, YI H L, GUO W W. Spontaneous generation and SSR characterization of polyploids from ten Citrus cultivars. Acta Horticulturae Sinica, 2014, 41(3): 409-416. (in Chinese)
[18]	陈林杨, 刘萍, 董蓉娇, 刘梦雨, 赵东兴, 杨永智, 赵志昆. 基于SSR分子标记的柚资源遗传多样性分析. 西南农业学报, 2020, 33(11): 2432-2438.
	CHEN L Y, LIU P, DONG R J, LIU M Y, ZHAO D X, YANG Y Z, ZHAO Z K. Genetic diversity analysis of pomelo resourses based on SSR molecular markers. Southwest China Journal of Agricultural Sciences, 2020, 33(11): 2432-2438. (in Chinese)
[19]	BARKLEY N A, ROOSE M L, KRUEGER R R, FEDERICI C T. Assessing genetic diversity and population structure in a Citrus germplasm collection utilizing simple sequence repeat markers (SSRs). Theoretical and Applied Genetics, 2006, 112(8): 1519-1531. doi: 10.1007/s00122-006-0255-9
[20]	夏强明, 彭珺, 解凯东, 伍小萌, 徐强, 郭文武. 以雄性不育胞质杂种‘华柚2号’为母本创制柚有性群体. 果树学报, 2019, 36(8): 961-967.
	XIA Q M, PENG J, XIE K D, WU X M, XU Q, GUO W W. Production of sexual hybrids with male sterile somatic cybrid pummelo ‘Huayou No.2’ as female parent. Journal of Fruit Science, 2019, 36(8): 961-967. (in Chinese)
[21]	WANG X, XU Y T, ZHANG S Q, CAO L, HUANG Y, CHENG J F, WU G Z, TIAN S L, CHEN C L, LIU Y, et al. Genomic analyses of primitive, wild and cultivated Citrus provide insights into asexual reproduction. Nature Genetics, 2017, 49(5): 765-772. doi: 10.1038/ng.3839
[22]	宋健坤, 朱世平, 谭美莲, 郭文武, 邓秀新. 沙田柚(2x)×柑橘异源体细胞杂种NS(4x)的三倍体后代遗传分析. 园艺学报, 2012, 39(6): 1021-1026.
	SONG J K, ZHU S P, TAN M L, GUO W W, DENG X X. Genetic analysis of triploid progenies from Shatian pummelo(2x) × Citrus allotetraploid somatic hybrid NS(4x). Acta Horticulturae Sinica, 2012, 39(6): 1021-1026. (in Chinese)
[23]	VILORIA Z, DROUILLARD D L, GRAHAM J H, GROSSER J W. Screening triploid hybrids of ‘Lakeland’ limequat for resistance to Citrus canker. Plant Disease, 2004, 88(10): 1056-1060. doi: 10.1094/PDIS.2004.88.10.1056
[24]	LOURKISTI R, FROELICHER Y, HERBETTE S, MORILLON R, TOMI F, GIBERNAU M, GIANNETTINI J, BERTI L, SANTINI J. Triploid Citrus genotypes have a better tolerance to natural chilling conditions of photosynthetic capacities and specific leaf volatile organic compounds. Frontiers in Plant Science, 2020, 11: 330. doi: 10.3389/fpls.2020.00330
[25]	SOOST R K, CAMERON J W. ‘oroblanco’, a triploid pummelo- grapefruit Hybrid1. HortScience, 1980, 15(5): 667-669. doi: 10.21273/HORTSCI.15.5.667
[26]	FABRONI S, RUBERTO G, RAPISARDA P. Essential oil profiles of new Citrus hybrids, a tool for genetic Citrus improvement. Journal of Essential Oil Research, 2012, 24(2): 159-169. doi: 10.1080/10412905.2012.659529
[27]	AHMED D, EVRARD J C, OLLITRAULT P, FROELICHER Y. The effect of cross direction and ploidy level on phenotypic variation of reciprocal diploid and triploid mandarin hybrids. Tree Genetics & Genomes, 2020, 16(1): 25.
[28]	SDIRI S, CUENCA J, NAVARRO P, SALVADOR A, BERMEJO A. New triploids late-maturing mandarins as a rich source of antioxidant compounds. European Food Research and Technology, 2020, 246(1): 225-237. doi: 10.1007/s00217-019-03407-9
[29]	ALEZA P, CUENCA J, JUÁREZ J, PINA J A, NAVARRO L. ‘Garbí’ mandarin: A new late-maturing triploid hybrid. HortScience, 2010, 45(1): 139-141. doi: 10.21273/HORTSCI.45.1.139
[30]	CUENCA J, ALEZA P, JUÁREZ J, PINA J A, NAVARRO L. ‘Safor’ mandarin: A new Citrus mid-late triploid hybrid. HortScience, 2010, 45(6): 977-980. doi: 10.21273/HORTSCI.45.6.977
[31]	CUENCA J, ALEZA P, JUÁREZ J, PINA J A, NAVARRO L. Two new Ivia triploid mandarin hybrids: ‘Alborea’ and ‘Albir’. Acta Horticulturae, 2015(1065): 209-214.
[32]	ESEN A, SOOST R K, GERACI G. Seed set, size, and development after 4x × 2x and 4x × 4x crosses in Citrus Euphytica, 1978, 27(1): 283-294. doi: 10.1007/BF00039144
[33]	YI H L, DENG X X. RAPD-based genetic analysis of offsprings from the sexual cross using allotetraploid Citrus somatic hybrid as pollen parent. Science in China Series C: Life Sciences, 2007, 50(3): 367-376.
[34]	SHIMADA T, ENDO T, FUJII H, NAKANO M, SUGIYAMA A, DAIDO G, OHTA S, YOSHIOKA T, OMURA M. MITE insertion- dependent expression of CitRKD1 with a RWP-RK domain regulates somatic embryogenesis in Citrus nucellar tissues. BMC Plant Biology, 2018, 18(1): 166. doi: 10.1186/s12870-018-1369-3
[35]	宋放, 羊林鑫, 王策, 蒋迎春, 何利刚, 王志静, 马小方, 张豫, 宋鑫, 吴黎明. 清见×鄂柑一号杂交F₁代亲缘关系及单多胚性鉴定. 果树学报, 2025, 42(5): 957-968.
	SONG F, YANG L X, WANG C, JIANG Y C, HE L G, WANG Z J, MA X F, ZHANG Y, SONG X, WU L M. Identification of phylogenetic relationship and polyembryony trait in F₁ hybrid offspring of Kiyomi and Egan No. 1. Journal of Fruit Science, 2025, 42(5): 957-968. (in Chinese)
[36]	梁武军, 解凯东, 谢宗周, 徐强, 伊华林, 郭文武. 三倍体葡萄柚实生后代多倍体的发掘与SSR遗传鉴定. 果树学报, 2015, 32(1): 13-18.
	LIANG W J, XIE K D, XIE Z Z, XU Q, YI H L, GUO W W. Exploitation of polyploids from open-pollinated triploid grapefruit progenies and their genetic identification by SSR molecular markers. Journal of Fruit Science, 2015, 32(1): 13-18. (in Chinese)

引物名称 Primer name	正向序列 Forward sequence (5′-3′)	反向序列 Reverse sequence (5′-3′)	参考文献Reference
P72	GTGAGGCAAAACGGAAAGAG	GGGCCCATACAACGTAGAAG	[16]
Ma3-96	ATCATTTCAACAAGGGACGG	TCGCCAATCAAACAACAAAA	[17]
P8	TTGCCAAGAGATTAAACGAACA	GACGAGAGGTCCAGAAATCG	[18]
COSC4-9	GTCCTCTTTTGACGCCTCCT	CCTTTGGGTTTGTTGGACGAC	[18]
CAG01	AACACTCGCACCAAATCCTC	TAAATGGCAACCCCAGCTTTG	[19]

品种 Cultivar	株高 Plant height (cm)	地径 Ground diameter (mm)	株高/地径 Plant height/Ground diameter
四倍体‘胡柚’×‘琯溪蜜柚’子代（n=40） Tetraploid Huyou × Guanximiyou	33.73±5.26a	5.97±0.73	5.65±0.62a
四倍体‘胡柚’×‘早香柚’（n=14） Tetraploid Huyou × Zaoxiangyou	26.03±7.83b	5.75±0.35	4.49±1.12b
四倍体‘胡柚’×‘东试早柚’（n=5） Tetraploid ‘Huyou × Dongshizaoyou	29.72±8.28ab	5.71±0.54	5.20±1.40ab
四倍体‘胡柚’×‘红宝石柚’（n=7） Tetraploid Huyou × Hongbaoshiyou	33.61±7.94a	5.69±0.65	5.91±0.95a
四倍体‘胡柚’ Tetraploid Huyou	27.00±3.84b	5.71±0.66	5.08±0.68ab

四倍体‘胡柚’与4个柚品种倍性杂交创制柑橘三倍体

Innovation of Citrus Triploids by Ploidy Hybridization Between Tetraploid Huyou and Four Pomelo Cultivars

RichHTML

PDF

赞

可视化

摘要/Abstract

引用本文

使用本文

图/表 9

参考文献 36

相关文章 15

Metrics

本文评价

推荐阅读 0

杂交组合 Cross	授粉花数 No. of flowers	坐果数 No. of fruits	坐果率 Fruit setting rate (%)	种子数 No. of seeds	再生植株 No. of plants	三倍体 No. of triploids
四倍体‘胡柚’×‘琯溪蜜柚’ Tetraploid Huyou×Guanximiyou	61	16	26.22	328	232	40
四倍体‘胡柚‘×‘早香柚’ Tetraploid Huyou×Zaoxiangyou	11	4	36.36	112	33	14
四倍体‘胡柚’×‘东试早柚’ Tetraploid Huyou×Dongshizaoyou	11	1	9.09	22	14	5
四倍体‘胡柚’×‘红宝石柚’ Tetraploid Huyou×Hongbaoshiyou	14	8	57.14	64	24	7
总计Total	97	29	29.90	526	303	66

[1]	栗方亮, 孔庆波, 张青. 基于光谱指数的琯溪蜜柚叶片钙素含量估测模型研究[J]. 中国农业科学, 2025, 58(7): 1321-1332.
[2]	关紫恒, 季润泽, 荣琪, 徐雨杰, 钟原, 成仿云. 分子核型分析揭示芍药属组间杂种新倍性及其产生机制[J]. 中国农业科学, 2025, 58(23): 4998-5012.
[3]	王璐璐, 张名位, 叶佳敏, 张瑞芬, 邓梅. 沙田柚果肉可溶和不溶性膳食纤维对肠道菌群的影响[J]. 中国农业科学, 2024, 57(20): 4119-4129.
[4]	叶佳敏, 张名位, 卢琦, 张瑞芬, 邓梅. 乳酸菌半固态发酵对沙田柚果粉苦味及活性成分的影响[J]. 中国农业科学, 2024, 57(13): 2662-2673.
[5]	江东, 王旭, 李仁静, 赵晓东, 戴祥生, 柳正葳. 基于GBS技术开展柚类资源群体遗传评价并发掘酸含量相关基因[J]. 中国农业科学, 2023, 56(8): 1547-1560.
[6]	卢艳清, 林燕金, 王贤达, 卢新坤. 基于转录组测序筛选与柚裂果相关的基因[J]. 中国农业科学, 2023, 56(20): 4087-4101.
[7]	程莉, 杨胜男, 朱延松, 王旭, 赵婉彤, 李仁静, 李沛, 苑忠杰, 江东. 柚果肉颜色遗传变异分析及候选基因挖掘[J]. 中国农业科学, 2023, 56(17): 3420-3434.
[8]	卢琦,贾栩超,邓梅,张瑞芬,董丽红,黄菲,池建伟,刘磊,张名位. 不同干制方式对沙田柚果渣粉活性物质的影响[J]. 中国农业科学, 2022, 55(14): 2825-2836.
[9]	宋彪,徐凯悦,王晓华,郭九信,吴良泉,苏达. 蜜柚果实不同空间部位植酸及矿质营养有效性的分布特征[J]. 中国农业科学, 2021, 54(6): 1229-1242.
[10]	解凯东,彭珺,袁东亚,强瑞瑞,谢善鹏,周锐,夏强明,伍小萌,柯甫志,刘高平,GROSSER Jude W,郭文武. 以本地早橘和槾橘为母本倍性杂交创制柑橘三倍体[J]. 中国农业科学, 2020, 53(23): 4961-4968.
[11]	王贤达, 范国成, 李健. 度尾文旦柚叶片矿质元素含量的适宜值[J]. 中国农业科学, 2020, 53(17): 3576-3586.
[12]	武炳超, 童磊, 杜昭昌, 胡家菱, 张欢, 陈燚, 刘伟, 张新全, 黄琳凯. ⁶⁰Co-γ射线对2种狼尾草属牧草的诱变效应[J]. 中国农业科学, 2019, 52(3): 414-427.
[13]	马亚茹，冯建灿，刘崇怀，樊秀彩，孙海生，姜建福，张颖. 葡萄无核性状的SSR新分子标记开发及应用[J]. 中国农业科学, 2018, 51(13): 2622-2630.
[14]	刘欢，张新全，马啸，张瑞珍，何光武，潘玲，金梦雅. 基于荧光检测技术的多花黑麦草EST-SSR指纹图谱的构建[J]. 中国农业科学, 2017, 50(3): 437-450.
[15]	刘秀云，李慧，刘志国，赵锦，刘孟军. 基于SSR标记的255个枣品种亲缘关系和群体遗传结构分析[J]. 中国农业科学, 2016, 49(14): 2772-2791.