Germplasm Resources Resistant to Leaf Spot Disease in Sugarbeet: Research Status

doi:10.11924/j.issn.1000-6850.casb18120028

Abstract

Abstract: Sugarbeet germplasm resources for resistance to Leaf spot diseas are the germplasm resources of sugarbeet germplasm which has resistance gene to Leaf spot diseas and can be transferred to offspring stably. It is the material basis of breeding for resistance to Leaf spot diseas, and also the strategic resource for sustainable development of agriculture.The main contents of research on sugar beet germplasm resources include the collection, identification and evaluation of sugar beet varieties, conservation and utilization, and the cloning and utilization of resistance genes.In order to make people more clear understanding of the research status of sugar beet resistance to Leaf spot disease germplasm resources.This paper reviews the collection, identification and evaluation, preservation and utilization of sugar beet germplasm resources, and molecular research, and prospects for future research on germplasm resources in China.In order to provide a direction for the future study of sugarbeet resistance to Leaf spot disease germplasm resources.

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References

[1]郑殿升,杨庆文,刘旭.中国作物种质资源多样[J].植物遗传资源学报,2011,12(4):497-500,506
[2]刘旭,李立会,黎裕,et al.作物种质资源研究回顾与发展趋势[J].农学学报,2018(1):1-6.
[3]Felipini R B, Luiz C, Costa M E B, et al. Mode of action of chitosan and ASM for the control of Cercospora leaf spot on table beet[J]. Tropical Plant Pathology, 2015, 40(3):176-183.
[5] 李雅华,崔平.我国非糖用甜菜种质资源及利用潜力[J].中国糖料,2003,(01):41-44.
[5]Panella L. REGISTRATION OF FC301, MONOGERM, O-TYPE SUGARBEET POPULATION RESISTANT TO RHIZOMANIA AND CERCOSPORA LEAF SPOT AND MODERATELY RESISTANT TO BLACK ROOT AND CURLY TOP.[J].
[6] Panella, L.W., Hanson, L.E. Breeding for resistance to Cercospora Leaf Spot: U.S. Perspective[J]. Phytopathology. 2006. 96:S141.
[7]Panella, L.W., Hanson, L.E. Notice of release of FC723CMS monogerm Sugarbeet Germplasm. Germplasm Release, 2006.
[8]Panella L. Registration of FC709-2 and FC727 Sugarbeet Germplasms Resistant to Rhizoctonia Root Rot and Cercospora Leaf Spot[J]. Crop Science, 1999, 39(1):298-299.
[9]Panella L, Hanson L E, Mcgrath J M, et al. Registration of FC305 Multigerm Sugarbeet Germplasm Selected from a Cross to a Crop Wild Relative[J]. Journal of Plant Registrations, 2015, 9(1):115-120.
[10]Panella L, Hanson L E. Registration of FC720, FC722, and FC722CMS monogerm sugarbeet germplasms resistant to Rhizoctonia root rot and moderately resistant to Cercospora leaf spot.[J]. Crop Science, 2006, 46(2):1009-1010.
[11]Panella L, Lewellen R T, Hanson L E. Breeding for Multiple Disease Resistance in Sugarbeet: Registration of FC220 and FC22 1[J]. 2008, 2(2):146-155.
[12]Agn? Sadauskien?, Zita Brazien?, Zenonas Dabkevi?ius. Fungal disease resistance of perspective sugar beet varieties and their yield potential[J]. 2018, 25(1)
[13] 鄂圆圆,白晨,张惠忠, et al.华北区甜菜种质资源的收集、鉴定、评价[J].内蒙古农业科技2015,(01):17-18+46.
[14] 崔平,潘荣.甜菜优异种质资源创新利用与评价[J].中国糖料,2005,(04):26-29+37.
[15] 高卫时,张立明,刘华君, et al.不同品种甜菜褐斑病抗性分析及早期鉴定方法[J].中国糖料,2011,(04):25-27+30.
[16] 杨安沛,曹禹,孙桂荣, et al.不同甜菜品种对褐斑病的抗性分析[J].中国糖料,2014,(4):48-49+25.
[17]Wang M Q, Bai C, Ze-Dong W U, et al. Identification of Disease Resistance to Root Rot and Leaf Spot of 18 Domestic and Foreign Sugarbeet Varieties[J]. Sugar Crops of China, 2015.
[18] 崔平,路运才,李雅华.甜菜种质资源的研究现状及其进展[J].中国糖料,1999,(2):44-47.
[19] 崔平,潘荣.我国甜菜种质资源研究与利用进展[J].中国糖料,2007,(3):25-55
[20]王燕飞. 国外甜菜育种特点及技术手段[J]. 新疆农业科学, 2005, 42(4):215-218.
[21] 倪洪涛.浅议甜菜品种褐斑病研究进展及随想[J].中国糖料,2002,(3):30-34.
[22] 夏红梅,杨宇博,韩新文, et al等.甜菜褐斑病的危害及其防治[J].中国甜菜糖业,2003,(1):53-55.
[23]Saunders J W, Theurer J C, Halloin J M. Registration of EL50 Monogerm Sugarbeet Germplasm with Resistance to Cercospora Leaf Spot and Aphanomyces[J]. Crop Science, 1999, 39(3):883.
[24]杨炎生, 孙以楚. 抗病偏高糖甜菜多倍体新品种甜研301的选育[J]. 中国农业科学, 1989, 22(1):29-34.
[25]杨炎生, 孙以楚. 甜菜多倍体新品种甜研302的选育[J]. 中国糖料, 1989(4):1-6.
[26]郑洪. 高糖兼抗病型甜菜多倍体品种甜研303甜研304简介[J]. 中国糖料, 1999(1)
[27]孙以楚, 杨炎生, 王华忠, et al. 甜菜多倍体新品种甜研304的选育[J]. 中国糖料, 1993(4):1-4.
[28]王红旗, 胡文信, 李宏侠, et al. 甜菜多倍体双交种──甜研308的选育[J]. 中国糖料, 1996(3):6-9.
[29]孙以楚, 张袖. 甜菜新品种——甜研201[J]. 新农业, 1992(1).
[30]胡文信. 甜研202品种的选育[J]. 中国甜菜糖业, 1991(6):14-18.
[31]Ya-Huai M A, Yan-Li L I, Bai Z C, et al. Breeding of Sugarbeet Variety ZM201 with High Yield, Disease Resistance and High Sugar Content[J]. Sugar Crops of China, 2008,(4):21-23
[32]Li Y L, Bai Z C, Ma Y H. Breeding of sugarbeet variety ZM202 with high yield and disease resistance.[J]. Sugar Crops of China, 2010(3):6-8.
[33] Smith, G.A., Gaskill, J.O. Inheritance of resistance to Cercospora leaf spot in sugarbeet[J]. Sugarbeet Techn. 1970,16:172–180.
[34]Schondelmaier J, Jung C. Chromosomal assignment of the nine linkage groups of sugar beet (Beta vulgaris L.) using primary trisomics[J]. Theoretical Applied Genetics, 1997, 95(4):590-596.
[35]Nilsson N O, Hansen M, Panagopoulos A H, et al. QTL analysis of Cercospora leaf spot resistance in sugar beet[J]. Plant Breeding, 2010, 118(4):327-334..
[36]Sch?fer-Pregl, R., Borchard, D.C., Barzen, E., et a Localization of QTLs for tolerance to Cercospora beticola on sugar beet linkage groups[J]. Theor. Appl. Genet,1999,99, 829-836.
[37] A. Setiawan ,G. Koch, S.R. Barnes,et al.Mapping quantitative trait loci (QTLs) for resistance to Cercospora leaf spot disease (Cercospora beticola Sacc.) in sugar beet (beta vulgaris l.)[J].Thaor Appl Genet ,2000,100:1176-1182.
[38]Koch, G. ,Jung, C. Genetic localization of Cercospora resistance genes[J]. Adv. Sugar Beet Res. IIRB, 2000,2: 197–210
[39]Kazunori T, Tomohiko K, Hiroyuki T, et al. Identification and Precise Mapping of Resistant QTLs of Cercospora Leaf Spot Resistance in Sugar Beet (Beta vulgarisL.)[J]. G3 (Bethesda, Md.), 2011, 1(4):283.
[40] Taguchi K, Okazaki K, Kuroda Y, et al. Molecular Dissection and Marker Assisted Selection to Cercospora Leaf Spot in Sugar Beet[C]// International Plant and Animal Genome Conference Xxiii. 2015.
[41] 刘大丽, 马龙彪, 纪岩, et al. 甜菜褐斑病抗性基因的克隆[J]. 中国糖料, 2017, 39(4):5-7.

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