我国木薯育种研究进展

严华兵,叶剑秋,李开绵

中国农学通报. 2015, 31(15): 63-70

PDF(543 KB)
PDF(543 KB)
中国农学通报 ›› 2015, Vol. 31 ›› Issue (15) : 63-70. DOI: 10.11924/j.issn.1000-6850.casb14110159
农学 农业基础科学

我国木薯育种研究进展

  • 严华兵,叶剑秋,李开绵
作者信息 +

Progress of Cassava Breeding in China

Author information +
History +

摘要

为了促进中国木薯选育种研究,就中国木薯产业发展需求,育成的主要木薯品种以及国内外木薯育种策略进行了综述,比较了不同育种策略在木薯育种应用上的优缺点,指出了下一阶段中国木薯育种的主要目标,并为中国木薯育种工作的顺利开展提出了几点建议。“十三五”期间,中国木薯产业将围绕“能源化、食用化、特用化、效益化、国际化”的目标进行,全面综合开发利用木薯资源以满足多元化市场的需求。

Abstract

To promote the progress of cassava breeding in China, the development of cassava industry in China, the major cultivars bred in China and the breeding strategies of cassava were overviewed in this paper. The advantages and disadvantages of the various strategies on cassava breeding were compared, which will be helpful for the cassava consordium. It also pointed out the major focus of cassava breeding in China, and shared some suggestions for cassava breeding in China. In the “Thirteen-Five Plan”, China’s cassava industry will focus on the target of “for energy, for food, for special benefit, for economy and for internationalization”, in order to diversify the market of cassava.

关键词

木薯;新品种;育种策略;育种目标

Key words

Cassava, New cultivars, Breeding strategies, Breeding focus

引用本文

EndNote

Ris (Procite)

Bibtex

导出引用
严华兵,叶剑秋,李开绵. 我国木薯育种研究进展. 中国农学通报. 2015, 31(15): 63-70 https://doi.org/10.11924/j.issn.1000-6850.casb14110159
Progress of Cassava Breeding in China. Chinese Agricultural Science Bulletin. 2015, 31(15): 63-70 https://doi.org/10.11924/j.issn.1000-6850.casb14110159

参考文献

[1] El-Sharkawy M A. Cassava biology and physiology [J]. Plant Molecular Biology, 2004, 56:481-501.
[2] Balagopalan C. Cassava utilization in food, feed and industry [A]. In: Hillocks R J, Thresh J M, Bellotti A C (eds). Cassava: biology, prod uction andutilization [C] CAB International, 2002, 301-318.
[3] 联合国粮农组织统计数据库,http://faostat3.fao.org/faostat-gateway/go/to/home/E
[4] Moorthy S N. Tropical sources of starch [A]. In: Eliasson AC (eds). Starch in food: structure, function and application [C]. Woodhead Publi shingLimited, 2004, 326-334.
[5] 林雄,李开绵,黄洁,等. 木薯新品种华南5号选育报告[J]. 热带农业科学,2001,5:15-20.
[6] 李开绵,林雄,黄洁,等. 华南6号木薯的选育[J]. 热带作物学报,2002,23(4):39-43.
[7] 叶剑秋,李开绵,陈丽珍,等. 木薯新品种华南7号的选育[J]. 热带作物学报,2007,28(1):24-29.
[8] 叶剑秋,黄洁,陈丽珍,等. 木薯新品种华南8号的选育[J]. 热带作物学报,2006,27(4): 19-25.
[9] 黄洁,单荣芝,李开绵,等. 优质鲜食木薯新品种华南9号[J]. 中国热带农业,2006,5:47.
[10]叶剑秋,郑永清,薛茂富,等. 木薯新品种华南10号的选育[J]. 热带作物学报,2011,32(10): 1799-1803.
[11]林雄,张伟特,王书媛,等. 木薯新品种华南8002和8013的育成报告[J]. 热带作物研究,1995,33-43.
[12]李开绵. 木薯新品种华南124的主要特点及其繁殖推广的方法和途径[J]. 热带作物研究,1991,56-61.
[13]黄洁. 木薯丰产栽培技术[A]. 海南:三环出版社,2007,26-34.
[14]田益农,李军,盘欢. 木薯新品种GR891的选育[J]. 广西农业科学,1998,3:124-125.
[15]李军,田益农. 木薯新品种GR911的选育[J]. 广西热作科技,1999,4:1-4.
[16]黄强,李军,田益农,等. 优良木薯品种桂热引1号的选育及栽培技术[J]. 湖南农业科学,2010,15:21-23.
[17]李军,黄强,田益农,等. 木薯品种桂热3号的选育及栽培技术[J]. 广西农业科学,2009,40(9):1147-1149.
[18]广西种业信息网,http://www.gxseed.com.cn/breed/Breed_Aud.asp
[19]罗兴录. 木薯新品种新选048选育与应用[J]. 中国农学通报,2009,25(24):501-505.
[20]Yan H B, Lu L Y, Hershey C, et al. Cassava mutation breeding: current status and trends [J]. Plant Mutation Reports, 2013, 3 (1): 37-44.
[21]Chavez A L, Ceballos H, Rodriguez A D B, et al. Sampling variation for crarotenoids and dry matter contents in cassava roots [J]. JournalofRoot Crops, 2008, 34(1): 43-49.
[22]Chavez A L, Sanchez T, Jaramillo G, et al. Variation of quality traits in cassava roots evaluated in landraces and improved clones [J]. Euph ytica, 2005, 143:125-133.
[23]Ceballos H, Sanchez T, Chavez A L, et al. Variation in crude protein content in cassava roots [J]. Journal of Food Composition and Analys is, 2006, 19: 589-593.
[24]Carvalho L J C B, Souza C R B, Cascardo J M C, et al. Natural genetic variation in cassava landraces: a tool for gene discovery [A]. In:Shu Q.Y.(Eds.). Induced plant mutations in the genomics era [C]. Food and Agriculture Organization of the United Nations, Rome, 2009,279 -282.
[25]Carvalho L J C B, Souza C R B, Cascardo J M C, et al. Identification and characterization of a novel cassava clone with high sugar conte nt andnovel starch [J]. Plant Molecular Biology, 2004, 56: 634-659.
[26]叶剑秋. 我国木薯选育种进展. 热带农业科学,2009,29(11): 115-120
[27]Kawano K, Narintaraporn K, Narintaraporn P, et al. Yield improvement in a multistage breeding program for cassava [J], Crop Science, 199 8, 38(2):325-332.
[28]Ceballos H, Fregene M, Carlos J P, et al. Cassava genetic improvement [A]. In: Kang M.S., Priyadarshan P.M. (Eds.). Breeding major food staples [C].Blackwell Publishing, 2007, 365-392.
[29]Rojas M C, Perez J C, Ceballos H, et al. Analysis of inbreeding depression in eight S1 cassava families [J]. Crop Sciences, 2009, 49: 543- 548
[30]Ceballos H, Kulakow P, Hershey C. Cassava breeding: current status, bottlenecks and the potential of biotechnology tools [J]. Tropical PlantBiology, 2012, 5 (1):73-87.
[31]Alves A A C. Cassava botany and physiology [A]. In: Hillocks R J, Thresh J M, Bellotti A C (eds). Cassava: biology, production and utili zation [C]. CAB International, 2002, 67-89.
[32]Nassar N M A. Cassava, Manihot esculenta Crantz, genetic resources: origin of the crop, its evolution and relationships with wild relatives [J]. Genetics and Molecuar Research, 2002, 1(4): 298-305.
[33]Nassar N M A. Wild cassava, Manihot spp. to improve the crop [J]. Gene Conserve, 2007, 6 (26): 387-414.
[34]Nassar N M A. Dry matter content in cassava and interspecific hybridization [J]. Genetics and Molecuar Research, 2010, 9(2): 608-610.
[35]Nassar N M A, Ortiz R. Cassava improvement: challenges and impacts [J]. Journal of Agricultural Science, 2007, 145: 163-171.
[36]Nassar N M A. Development of cassava interspecific hybrids for savanna (cerrado) conditions [J]. Journal of Root Crops, 1996, 22: 9-17.
[37]Li H Q, Sautter C, Potrykus I, et al. Genetic transformation of cassava (Manihot esculenta Crantz) [J]. Nature Biotechnology, 1996, 14:73 6–740.
[38]Schopke C, Taylor N, Carcamo R, et al. Regeneration of transgenic cassava (Manihot esculenta Crantz) plants from microbombarded embryo genic suspension cultures [J]. Nature Biotechnology, 1996, 14: 731–735.
[39] Taylor N, Chavarriaga P, Raemakers K, et al. Development and application of transgenic technologies in cassava [J]. Plant Molecular Biology, 2004, 56: 671-688.
[40]Liu J, Zheng Q J, Ma Q X, et al. Cassava genetic transformation and its application in breeding [J]. Journal of Integrative Plant Biology, 2 011, 53(7): 552-569.
[41]Siritunga D, Sayre R T. Generation of cyanogen-free transgenic cassava [J]. Planta, 2003, 217: 367-373.
[42]Agnes RS, Teresa S, Alain B, et al. Molecular and supra-molecular structure of waxy starches developed from cassava (Manihot esculenta C rantz) [J]. Carbohydrate Polymers, 2013, 92: 1451-1462.
[43] Saelim L, Phansiri S, Suksangpanomrung M, et al. Evaluation of a morphological marker selection and excision system to generate marker-free transgenic cassava plants [J]. Plant Cell Reports, 2009, 28: 445-455.
[44]Henikoff S, Till B J, Comai L. TILLING - Traditional mutagenesis meets functional genomics [J]. Plant physiology, 2004, 135: 630-636.
[45]Chen Z J, Birchler JA (eds). Polyploid and hybrid genomics [M]. Wiley Blackwell, New York, 2013.
[46]Sreekumari M T, Jos J S, Nair S G. “Sree Harsha”: a superior triploid hybrid in cassava, Euphytica, 1999, 106: 1-6.
[47]Dhooghe E, Laere K V, Eeckhaut T, et al. Mitotic chromosome doubling of plant tissues in vitro [J]. Plant Cell, Tissue and Organ Culture, 2011, 104: 359-373.
[48]王家利,王芳,郭小丽,等. 同源多倍体化效应研究进展[J]. 中国农学通报,2013,29(12):22-29.
[49]Awoleye F, Duren M V, Dolezel J, et al. Nuclear DNA content and in vitro induced somatic polyploidization cassava (Manihot esculenta Cr antz) breeding [J]. Euphytica, 1994, 76: 195-202.
[50]Nassar N M A. Polyploidy, chimera and fertility of interspecific cassava (Manihot esculenta Crantz) hybrids [J]. The Indian Journal of Genet ics and Plant Breeding, 2004, 64 (4): 317-318.
[51]Nassar N, Bomfim N N, Elsayed A Y, et al. Interesting cassava cultivars UnB 201 [J]. Geneconserve, 2011, 40: 163-165.
[52]Ribeiro D G, Nassar N M A. A comparative anatomical study in cassava diploid and tetraploid hybrids [J]. Plant Systematics and Evolution, 2012, 298: 1711-1721.
[53]陆柳英,谢向誉,严华兵. 秋水仙素诱导木薯多倍体研究进展[J]. 农学学报,2014,4(1):44-47.
[54]安飞飞,凡杰,李庚虎,等. 华南8号木薯及其四倍体诱导株系叶片蛋白质及叶绿素荧光差异分析[J]. 中国农业科学,2013,46(19):3978-3987.
[55]Mba C, Afza R, Cieslak J J, et al. Enhancing genetic diversity through induced mutagenesis in vegetatively propagated plants [A]. In: Shu QY (ed.) Induced plant mutations in the genomics era, Food and Agriculture Organization of the United Nations, Rome, 2009, 262-265.
[56]Nwachukwu E C, Mbanaso E N A Ene L S O. Improvement of cassava for high dry matter, starch and low cyanogenic glucoside content b y mutation induction [J]. IAEA-tecdoc, 951: 93-98.
[57]Asare E, Kantanka O S. Improvement of cassava cooking quality through mutation breeding [J]. IAEA-tecdoc, 951: 19-24.
[58]Ahiabu R K, Lokko Y, Danso K, et al. Mutagenesis for ACMVresistance in a ghanian cassava cultivar “Bosom Nsia” [J]. IAEA-tecdoc, 9 51: 9-18
[59]Lee K S, Duren M V, Morpurgo R. Somatic embryogenesis in cassava: a tool for mutation breeding [J]. IAEA-tecdoc, 951: 55-59.
[60]Owoseni O, Okwaro H, Afza R, et al. Radiosensitivity and in vitro mutagenesis in African accessions of cassava (Manihot esculenta Crantz) [J]. Plant Mutation Reports, 2006, 1 (2): 32-36.
[61]Joseph R, Yeoh H H, Loh C S. Induced mutations in cassava using somatic embryos and the identification of mutant plants with altered sta rch yield and composition [J]. Plant Cell Report, 2004, 23: 91-98.
[62]Sanchez T, Roserob A, Tofino A P, et al. Induction and identification of useful mutations for root quality traits in cassava, Shu QY (ed.) I nduced plant mutations in the genomics era, Food and Agriculture Organization of the United Nations, Rome, 2009, 266-269.
[63]陆柳英,朱文丽,莫饶,等. 化学诱变筛选木薯抗寒突变体的初步研究[J]. 广西农业科学,2007,38(5):499-494.
PDF(543 KB)

文章所在专题

油料作物

Accesses

Citation

Detail
段落导航
相关文章

/