Research Progress and Prospect on Sugarbeet Genetic Engineering

Abstract

CLC Number:

Q943.2

Sun Yaqing, Shao Jinwang, Zhang Shaoying. Research Progress and Prospect on Sugarbeet Genetic Engineering[J]. Chinese Agricultural Science Bulletin, 2007, 23(4): 27-27.

[1] 张艳春,黄祥辉,邵金旺.甜菜转基因研究进展.中国糖料,2002,(1):34-36.
[2] 王瑞刚,李国婧,邵金旺.甜菜抗病研究现状及其展望.中国糖料,2000,(4):51-54.
[3] 姚华建,李大伟,于嘉林,等.甜菜坏死黄脉病毒外壳蛋白基因在甜菜转基因植株中的表达.生物工程学报,1997,13(4):440-442.
[4] 张素珍,向本春,席德慧,等.抗丛根病转基因甜菜田间试验简结.石河子科技,2000,(1):2-3.
[5] 刘巧红,徐德昌,孔凡江,等.基因工程方法在抗甜菜丛根病育种中的应用.中国甜菜糖业,2000,(1):17-19.
[6] 徐德昌,刘巧红,江莉萍.甜菜转基因植株抗性表现及种子获得.中国甜菜糖业,2003,(4):3-4.
[7] 郝秀英,于嘉林,王燕飞,等.新疆甜菜品种(系)基因转化和再生体系的建立.中国糖料,2002,(4):5-7.
[8] 徐伟丽,徐德昌,刘巧红,等.第三代转基因甜菜植株的检测.中国甜菜糖业,2006,(1):22-23.
[9] 马龙彪,徐香玲,张悦琴,等.几丁质酶基因转化甜菜的研究.中国糖料,2000,(3):8-10.
[10] Tertivanidis K, Goudoula C, Vasilidiotis C, et al. Superoxide dismutase transgenes in sugarbeet confer resistance to oxidative ageuts and the fungus C.beticola. Transgenic Research, 2004, PC1193:1-9.
[11] Hunger S, Di Gaspero G, Mohring S, et al. Isolation and linkage analysis of expressed disease-resistance gene analogues of sugar beet (Beta vulgaris L.).Genome, 2003,46(1):70-82.
[12] J Morris, G T G Clover, V A Harjus, et al. Development of a highly sensitive nested RT-PCR method for Beet necrotic yellow vein virus detection. Journal of Virobogical Methods, 2001,95:163-169.
[13] Koenig R, Buttner G. Strategies for the detection of potential beet necrotic yellow vein virus genome recombination which might arise as a result of growing A type coat protein gene-expressing sugar beets in soil containing B type virus. Transgenic research,2004,13(1):21-28.
[14] Andika IB, Kondo H, Tamada T. Evidence that RNA silencing-mediated resistance to beet necrotic yellow vein virus is less effective in roots than in leaves. Mol Plant Microbe Interact,2005,18(3):194-204.
[15] 崔杰,李滨胜.抗虫基因及甜菜抗虫转基因研究现状.中国甜菜糖业,2004,(1):38-41.
[16] 李红侠,张文彬.甜菜抗虫转基因研究现状.中国甜菜糖业,2004,(2):16-18.
[17] D G Cai, M Kleine, S Kifle, et al. Positional cloning of a gene for nematode resistance in sugar beet. Science, 1997,275(7):832-834.
[18] T Thurau S, Kifle C Jung, et al. The promoter of the nematode resistance gene Hs1pro-1 activates a nematode-responsive and feeding site-specific gene expression in sugarbeet Beta vulgaris L.) and Arabidopsis thaliana. Plant Molecular Biology, 2003, 52:643-660.
[19] 庞洪泉.甜菜NBS-LRR类抗性基因序列分析及其转基因体系研究:[学位论文].杭州:浙江大学,2004:25-37.
[20] Suren S, Michael K, Carolien P, et al. Cloning and functional analyses of a gene from sugarbeet up-regulated upon cyst nematode infection. Plant Molecular Biology, 2004,1:1-10.
[21] 李红侠,马龙彪,张文彬.国外转基因抗除草剂甜菜研究.中国糖料,2005,(1):49-51.
[22] Lonard Gianessi, et al. Plant Biotechnology: Potential Impact for Improving Pest Management in European Agriculture: Sugarbeet Case Study[EB/OL].http://www.ncfap.org/reports.Europe/Herbicide Toletant Sugarbeet. pdf.2003-7-16/2006-12-10
[23] EM Kishchenko, IK Komarnitskii, NV Kuchuk. Production of transgenetic sugarbeet(Beta vulgaris L.) plants resistance to phosphinothricin. Cell Biology International, 2005,129:15-19.
[24] 李天然,张剑锋,李旭刚.抗冻冷蛋白基因转化甜菜的研究.内蒙古大学学报,1998,29(1):144-146.
[25] 刘宝辉.玉米蔗糖磷酸合成酶（SPS）基因的克隆及对甜菜遗传转化的研究:[学位论文].哈尔滨:东北农业大学,2003:22-35.
[26] 杨敏.荷兰育成低热量糖转基因甜菜.农村实用技术,2006,(3):10.
[27] Kishchenko EM, Komarnitskii IK, Kuchuk NV. Production of transgenic sugarbeet plants (Beta vulgaris L.) using Agrobacterium rhizogenes. Tsitol Genet, 2005,39(1):9-13.
[28] H Hisano, Y Kimoto, H Hayakawa, et al. High frequency Agrobacterium-mediated transformation and plant regeneration via direct formation from leaf explants in Beta vulgaris and Beta maritime. Plant Cell Report, 2004,22:910-918.
[29] Golovko AE, Dovzhenko AA, Gleba IuIu. Genetic transformation of sugar beet: evolution of theoretical and experimental approaches. Tsitol Genet, 2005,39(3):30-36.
[30] A F Yang, X G Duan, X F Gu, et al. Efficient transformation of beet(Beta vulgaris L.) and production of plants with improved salt-tolerance. Plant Cell, Tissue and Organ Culture, 2005,83:259-270.
[31] Snezana D, Ivic-Haymes, Ann C. Biolistic transformation of highly regeneration sugarbeet(Beta vulgaris L.) leaves. Plant Cell Report, 2005,23:699-704.
[32] Jimmy B.Food produced from glyphosate-tolerant sugarbeet line77[EB/OL].Food Standards Australia New Zealand 2003. http://www.foodstandards.gov.au/srcfiles/ TRX%20A378%20 Sugar % 20Beet% 2077.pdf.2003-5-24/2006-12-10
[33] 贾士荣.转基因作物的环境风险分析研究进展.中国农业科学,2004,37(2):175-187.
[34] 张海霞,张少英,白薇,等.提高甜菜遗传转化效率的研究.中国糖料,2005,(1):6-8.

Research Progress and Prospect on Sugarbeet Genetic Engineering

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 7

Recommended Articles

Metrics

Comments

For authors

For reviewers

Reader center

Contact us

[1]	. Bioinformatics Analysis of Berberine Bridge Enzyme in Papaver Somniferum L. [J]. Chinese Agricultural Science Bulletin, 2012, 28(10): 225-229.
[2]	Song Jianghua, Zhang Lixin. Research Advances on Gene Engineering of Pollen Development in Plants [J]. Chinese Agricultural Science Bulletin, 2008, 24(12): 92-95.
[3]	Li Huijuan, Sun Jianquan, Li Junfeng. Research Advances of Fructan Biosynthesis, Relevant Genes and its Function in Higher Plants [J]. Chinese Agricultural Science Bulletin, 2007, 23(9): 86-86.
[4]	Wang Ying, Zhuang Nansheng, Huang Dongyi. Research Advance in Applications of Specific DNA Sequences in Plants [J]. Chinese Agricultural Science Bulletin, 2007, 23(5): 37-37.
[5]	Su Qi, Shang Yuhang, Du Miying, Du Jinmin. Progress on Plant WRKY Transcription Factor [J]. Chinese Agricultural Science Bulletin, 2007, 23(5): 94-94.
[6]	Liu Wu, Dai Liangying. ERF Transcription Factors Related to Plant Stress-Tolerance [J]. Chinese Agricultural Science Bulletin, 2007, 23(4): 78-78.
[7]	Lin Bingying,, Li mei, Lin Deqin, Jin Zhiqiang. Cloning and Functional Analysis on Promoter of Tomato Fruit-specific 2A11 from Lycopersicon esculentum [J]. Chinese Agricultural Science Bulletin, 2006, 22(10): 62-62.