Plant Cell Engineering Applied in Wheat Breeding for the Resistance to FusariumHead Blight

doi:10.19586/j.2095-2341.2021.0120

Current Biotechnology ›› 2021, Vol. 11 ›› Issue (5): 574-580.DOI: 10.19586/j.2095-2341.2021.0120

• Resistant Resources to Fusarium Head Blight and Germplasm Innovation • Previous Articles Next Articles

Plant Cell Engineering Applied in Wheat Breeding for the Resistance to FusariumHead Blight

Yonggang WANG¹(), Xu ZHANG², Peng ZHANG², Hongxiang MA¹()

^1.Jiangsu Key Laboratory of Crop Genomics and Molecular Breeding； Key Laboratory of Plant Functional Genomics of the Ministry of Education，Jiangsu Co?innovation Center for Modern Production Technology of Grain Crops，College of Agriculture，Yangzhou University，Jiangsu Yangzhou 225009，China
^2.Jiangsu Provincial Key Laboratory of Agrobiology，Institute of Food Crops，Jiangsu Academy of Agricultural Sciences，Nanjing 210014，China

Received:2021-06-16 Accepted:2021-07-15 Online:2021-09-25 Published:2021-10-08
Contact: Hongxiang MA

植物细胞工程在小麦抗赤霉病育种中的应用

王永刚¹(), 张旭², 张鹏², 马鸿翔¹()

^1.扬州大学农学院，江苏省粮食作物现代产业技术协同创新中心，江苏省作物基因组学与分子育种重点实验室；植物功能基因组学教育部重点实验室，江苏扬州 225009
^2.江苏省农业科学院粮食作物研究所，江苏省农业生物学重点实验室，南京 210014

通讯作者: 马鸿翔
作者简介:王永刚 E-mail: Yg.Wang@yzu.edu.cn；
基金资助:
国家现代农业产业技术体系项目(CARS-03)

Abstract

Abstract:

Fusarium head blight is a worldwide destructive disease affecting the yield and quality in wheat， and Fusarium mycotoxin further threatens the health of human and livestock. Wheat resistant cultivars breeding is effective to control the disease. Plant cell engineering can produce novel genetic variation and accelerate the breeding process and has been successfully applied in wheat breeding for the resistance to Fusarium head blight. We reviewed the progress of plant cell engineering technologies such as somaclonal variation induction， anther culture， double haploid creation and immature embryo culture， and the application of these technologies in wheat breeding for the resistance to Fusarium head blight. Combination of plant cell engineering with molecular breeding will play a more important role in wheat breeding for the resistance to Fusariumhead blight.

Key words: wheat, plant cell engineering, Fusarium head blight, breeding

摘要：

小麦赤霉病是全球性小麦病害，严重影响小麦产量和品质，赤霉菌产生的毒素进一步威胁人畜安全，培育抗病品种是控制小麦赤霉病危害的根本途径。植物细胞工程技术可创造新的遗传变异、加快育种进程，已经广泛应用于小麦抗赤霉病育种。概述了体细胞无性系变异诱导、花药培养、小麦与玉米杂交培育加倍单倍体以及幼胚培养一年多代快速成苗等植物细胞工程技术研究进展，着重介绍了其在抗小麦赤霉病育种中的应用。最后对未来发展趋势做了展望，植物细胞工程结合分子育种技术将在小麦抗赤霉病品种培育中发挥更重要的作用。

关键词: 小麦, 植物细胞工程, 赤霉病, 育种

CLC Number:

S435.121.4+5

Yonggang WANG, Xu ZHANG, Peng ZHANG, Hongxiang MA. Plant Cell Engineering Applied in Wheat Breeding for the Resistance to FusariumHead Blight[J]. Current Biotechnology, 2021, 11(5): 574-580.

王永刚, 张旭, 张鹏, 马鸿翔. 植物细胞工程在小麦抗赤霉病育种中的应用[J]. 生物技术进展, 2021, 11(5): 574-580.

Figures/Tables 3

References 42

1	汪勋清,刘录祥.植物细胞工程研究应用与展望[J].核农学报,2008,22(5):635-639.
2	MA H, ZHANG X, YAO J, et al.. Breeding for the resistance to Fusarium head blight of wheat in China [J]. Front. Agric. Sci. Eng., 2019, 6(3):251-264.
3	LARKIN P J, SCOWCROFT W R. Somaclonal variation—a novel source of variability from cell-cultures for plant improvement [J]. Theor. Appl. Genet., 1981, 60: 197-214.
4	高明尉,成雄鹰,胡天赐,等.小麦体细胞无性系变异新品种核组8号的选育与表现[J].浙江农业科学,1992(6):261-263.
5	马鸿翔,陆维忠.小麦赤霉病抗性改良研究进展[J].江苏农业学报,2010,26(1):197-203.
6	陆维忠,佘建明,吴鹤鸣,等.小麦幼穗、茎、节组织培养和植株再生[J].江苏农业学报,1988,4(1):14-18.
7	陆维忠,程顺和,沈晓蓉,等.细胞工程在小麦抗赤霉病育种中的利用[J].江苏农业学报,1998, 14(1):9-14.
8	BAI G H, DESJARDINS A E, PLANTTNER R D. Deoxynivalenol-nonproducing Fusarium graminearum causes initial infection, but does not cause disease spread in wheat spikes [J]. Mycopathologia, 2002, 153(2):91-98.
9	YANG Z, YANG X, HUANG D. Studies on somaclonal variants for resistance to scab in bread wheat (Triticum aestivum L.) through in vitro selection for tolerance to deoxynivalenol [J]. Euphytica, 1998, 101(2):213-219.
10	郭丽娟,姚庆筱,胡启德,等.通过组织培养筛选小麦抗赤霉病突变体的研究[J].遗传学报,1992,19(3):259-265.
11	郭丽娟,姚庆筱,张春,等.利用细胞工程技术筛选小麦抗病新种质的研究[J].遗传学报,1996,23(1):40-47.
12	王裕中,陈怀谷,杨新宁,等.禾谷镰刀菌粗毒素的生物活性及其在小麦品种抗赤霉病性鉴定中的应用[J].中国农业科学,1989,22(4):54-57.
13	陈耀锋,韩德俊,李春莲,等.普通小麦抗赤霉细胞工程育种研究Ⅰ.抗镰刀菌毒素细胞变异系的分离[J].农业生物技术学报,1998,6(3):217-221.
14	陆维忠,蒋宁,周楠,等.小麦抗赤霉病无性系变异的研究与应用[J].农业生物技术学报,1995,3(2):7-11.
15	刘进平,郑成木,胡新文.体细胞无性系变异研究进展[J].华南热带农业大学学报,2001,7(2):22-29, 34.
16	周楠,陆维忠,葛美蓉.小麦体细胞无性系变异的同工酶分析[J].江苏农业学报,1991,7(3):17-22.
17	吴鹤鸣,陆维忠,周楠.小麦体细胞再生株(R1)的染色体变异分析[J].植物学报,1992,34(3):226-232.
18	沈晓蓉,陆维忠,许仁林,等.小麦体细胞无性系895004与供体亲本的抗赤性农艺性状比较和RAPD分析[J].江苏农业学报,1996,12(1):7-10.
19	向阳海,陆维忠,朱作为,等.小麦品种"扬麦158"与其两个抗赤霉病突变系的AFLP分析[J].江苏农业学报,2001,17(3):190-192.
20	陆维忠,程顺和,马鸿翔,等.优质、高产、抗赤霉病小麦新品种—生选3号[J].江苏农业学报,2003,19(2):69.
21	黄承彦,颜廷进,张存良,等.不同世代小麦花药培养的遗传效应分析[J].作物学报,1991,17(4):304-310.
22	章静娟,沈晓蓉,周淼平,等.不同杂交组合对小麦花粉植株再生的影响[J].江苏农业学报,1998,14(4):198-202.
23	陆维忠,马鸿翔.高产抗赤霉病小麦新品种生选6号的选育[J].江苏农业科学,2010(5):153-154.
24	蔡华,马传喜,周淼平,等.小麦与玉米远缘杂交诱导小麦单倍体的研究[J].麦类作物学报,2004,24(2):11-14.
25	王广金.小麦与玉米杂交产生单倍体频率的研究[J].麦类作物学报,1998,18(6):12-14.
26	蔡华,马传喜,黄正来,等.小麦×玉米诱导小麦单倍体高效系统的建立[J].核农学报,2006,20(2):90-94.
27	蔡华,马传喜,司红起,等.利用小麦与玉米远缘杂交诱导小麦双单倍体的研究进展[J].麦类作物学报,2006,26(4):154-157.
28	陈新民,徐惠君,周俊芳,等.提高小麦×玉米胚培养植株产生频率的研究[J].中国农业科学,1996,29(4):29-32.
29	吕国锋,范金萍,高德荣,等.胚龄对小麦×玉米单倍体植株产生的影响[J].江苏农业学报,2003,19(1):59-60.
30	蔡华,马传喜,乔玉强,等.小麦×玉米单倍体植株再生体系的建立[J].激光生物学报,2007,16(1):43-48.
31	陈新民,张文祥,崔淑兰,等.小麦×玉米产生小麦单倍体的染色体加倍研究[J].中国农业科学,2002,35(4):447-450.
32	陆维忠,姚金保,马鸿翔.抗赤霉病小麦新品种宁麦20的选育[J].江苏农业科学,2013,41(7):86-87.
33	王海波,王彦霞,赵和.如何加快作物遗传改良的速度[J].河北农业科学,2003,7(3):50-56.
34	张鹏,霍燕,马鸿翔.外源添加物对小麦幼胚成苗质量的影响[J].麦类作物学报,2009,29(1):31-34.
35	张鹏,霍燕,马鸿翔.麦芽提取物对小麦幼胚成苗培养及淀粉酶活性的影响[J].江苏农业学报,2009,25(3):703-705.
36	张鹏,王磊,杨学明,等.幼胚培养与标记辅助选择培育抗赤霉病小麦新种质[J].江苏农业科学,2012,40(11):70-71.
37	REICHERT N A. History of plant genetic mutations ± human influences [J/OL]. In Vitro Cell. Dev. Biol. Plant, 2021,doi: 10.1007/s11627-021-10182-4[2021-08-10]. .
38	DWIVEDI S L, BRITT A B, TRIPATHI L, et al.. Haploids: constraints and opportunities in plant breeding [J]. Biotechnol. Adv., 2015, 33(6):812-829.
39	NIU Z, JIANG A, HAMMAD W A, et al.. Review of doubled haploid production in durum and common wheat through wheat×maize hybridization [J]. Plant Breed., 2014, 133(3):313-320.
40	LYU J, YU K, WEI J, et al.. Generation of paternal haploids in wheat by genome editing of the centromeric histone CENH3 [J]. Nat. Biotechnol., 2020, 38(12):1397-1401.
41	RÓEWICZ M, WYZIŃSKA M, GRABIŃSKI J. The most important fungal diseases of cereals-problems and possible solutions [J/OL]. Agronomy, 2021, 11(4):714[2021-08-10]. .
42	FERNANDO W G D, OGHENEKARO A O, TUCKER J R, et al.. Building on a foundation: advances in epidemiology, resistance breeding, and forecasting research for reducing the impact of Fusarium head blight in wheat and barley [J]. Can. J. Plant Pathol., 2021, 43(4):495-526.

[1]	Zhenhua XU, Shiwei GAO, Dawei GAO, Yanming YU, Haiying LIU, Hongtao WU, Shuli ZHANG, Zhongyi SUN, Xin WANG, Ping YAN. Biological Breeding Science and Technology Innovation for Seed Industry Development and Prospects [J]. Current Biotechnology, 2025, 15(4): 557-564.
[2]	Ziya GAO, Bingxin HUANGFU, Jiake LI, Fangqian LI, Zhihao MA, Yang PANG, Jingang LIANG, Xiaoyun HE. Risk Identification and Suggestions for the Industrialization of Biological Breeding——based on Grower Field Research [J]. Current Biotechnology, 2025, 15(3): 456-465.
[3]	Mengqi FANG, Ying ZHAO, Zichen WANG, Wenhao JIA, Hui WANG, Yunxia LUAN. Establishment and Application of Aptamer-based Fluorescent Test Strip Method for the Detection of Alternariol [J]. Current Biotechnology, 2024, 14(6): 1024-1031.
[4]	Caihua LI, Yankun ZHAO, Zhankun LI, Zilong SHAN, Qiao CAO, Liang MA, Fei WANG, Zhenxian GAO. Research Progress on Rht Genes in Wheat [J]. Current Biotechnology, 2024, 14(6): 980-992.
[5]	Jing WANG, Haitao GUAN, Xiaolei ZHANG, Baohuai WANG, Baohai LIU, Hongtao WEN. Detection Dynamic and Development Tendency of Agricultural Gene Editing Products [J]. Current Biotechnology, 2024, 14(5): 712-723.
[6]	Mingyang JIA, Lei WANG, Junfeng CHEN, Jiaqing ZHANG, Xiangzhou YAN, Baosong XING, Jing WANG. Research Progress of CRISPR/Cas9 Gene Editing Technology in Livestock and Poultry Breeding [J]. Current Biotechnology, 2024, 14(4): 529-536.
[7]	Liwen WANG, Jiangkun WANG, Bingbing WANG, Jianhong XU, Jianrong SHI, Xin LIU. Roles of Fusarium Toxins in Plant-pathogen Interaction [J]. Current Biotechnology, 2024, 14(2): 182-188.
[8]	Kehao CAO, Junli ZHU, Huashan HE, Weizhuo XU. Impact of the Fourth Modifications of Patent Laws on Biotechnology Patent Applications and Industry Development [J]. Current Biotechnology, 2023, 13(5): 663-670.
[9]	Guizhen GAO, Yungu ZHAI, Lubin ZHANG, Jinmei CHANG, Haihua LUO, Xiaoming WU. Advances on Germplasm Identification and Variety Breeding to Saline-alkali Stress of Rapeseed [J]. Current Biotechnology, 2022, 12(5): 647-654.
[10]	Meicui YANG, Shihui ZHAO, Yuan GAO, Haoran SHI, Yun LI, Wanzhuo GONG, Jin YANG, Jisheng WANG, Qiong ZOU, Lanrong TAO, Zeming KANG, Rong TANG, Shixing GUO, Shaohong FU. Advances on Double Haploid Induction Breeding Technology in Rapeseed [J]. Current Biotechnology, 2022, 12(5): 655-663.
[11]	Tingting LIU, Tao TONG, Kunlun HUANG. Research Progress and Safety Evaluation of Transgenic Corn [J]. Current Biotechnology, 2022, 12(4): 523-531.
[12]	Xing DANG, Binwei ZHI, Kehao CAO, Tingting LIU, Biao CHEN, Yuanjie DING. Patent Analysis on Genetically Modified Maize Biological Breeding Technology and Development Suggestions [J]. Current Biotechnology, 2022, 12(4): 614-622.
[13]	Yunyan FEI, Jun YANG, Dedao JING, Tianzi LIN, Chuang LI, Huafei QIAN, Shengyuan ZENG, Huaxin HAN, Hongbing GONG. Research and Application Progress of CRISPR/Cas Technology in Herbicide⁃resistant Crops Breeding [J]. Current Biotechnology, 2022, 12(2): 189-197.
[14]	Yaohui HUANG, Yijie WANG, Litao YANG, Yue JIAO, Zhongwen FU. Safety Management of the Crop Produced by New Breeding Techniques [J]. Current Biotechnology, 2022, 12(2): 198-204.
[15]	Qiao CAO, Zhanliang SHI, Guocong ZHANG, Jinfu BAN, Shusong ZHENG, Xiaoyi FU, Shichang ZHANG, Mingqi HE, Ran HAN, Zhenxian GAO. Progress of CRISPR/Cas9 Application in Wheat Breeding [J]. Current Biotechnology, 2021, 11(6): 661-667.

Plant Cell Engineering Applied in Wheat Breeding for the Resistance to FusariumHead Blight

植物细胞工程在小麦抗赤霉病育种中的应用

RichHTML

PDF

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 3

References 42

Related Articles 15

Recommended Articles

Metrics

Comments