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微信公众号：大豆科学

[1]郑蔚虹,田成亮　吴俊江　刘丽君**　孙剑秋.东北地区不同大豆品种间的 RAPD 分析*[J].大豆科学,2005,24(02):130-134.[doi:10.11861/j.issn.1000-9841.2005.02.0130]
　Zheng WeihongTian ChengliangWu JunjiangLiu Liyun**Sun Jianqiu.STUDIES ON GENETIC RELATIONSHIPS AMONG NORTHEASTSOYBEAN CULTIVARS OF CHINA BY RAPD[J].Soybean Science,2005,24(02):130-134.[doi:10.11861/j.issn.1000-9841.2005.02.0130]

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东北地区不同大豆品种间的 RAPD 分析*

《大豆科学》[ISSN:1000-9841/CN:23-1227/S] 卷: 第24卷期数: 2005年02期页码: 130-134 栏目: 出版日期: 2005-05-25

Title:: STUDIES ON GENETIC RELATIONSHIPS AMONG NORTHEASTSOYBEAN CULTIVARS OF CHINA BY RAPD

作者:: 郑蔚虹¹; 3　田成亮³　吴俊江²　刘丽君^2**　孙剑秋³; (1. 温州大学生命与环境科学学院, 温州 325027;2. 黑龙江省农业科学院大豆研究所,哈尔滨 150086 ;3. 齐齐哈尔大学生命科学与工程学院生物系 ,齐齐哈尔 161006)

Author(s):: Zheng Weihong1; 3　Tian Chengliang3　Wu Junjiang2　Liu Liyun2**　Sun Jianqiu3; (1. School of Li f e and Environmental Sciences , Wenzhou University , Wenzhou 325027;2.Soybean, Institute Heilongjiang Academy of Agricultural Science Harbin 150086;3.Collegeof Lif e Science and Technology , Qiqihar University , Qiqihar 161006)

关键词:: 大豆; 亲缘关系; RAPD

Keywords:: Soybean ; Cultivars; Genetic relationships; RAPD

DOI:: 10.11861/j.issn.1000-9841.2005.02.0130

文献标志码:: A

摘要:: 实验采用 RAPD 技术对我国东北地区不同生态区的野生大豆和栽培的大豆品种材料进行了种间遗传关系分析。9 个引物共扩增出 141个片段 ,其中同源片段 6 个 ,特异性片段 21 个, 多态性片段 114 个, 显示出东北地区栽培的大豆品种间具有良好的多态性。通过 NTSYS 软件对RAPD 结果进行 UPGMA 聚类分析, 得到了各品种间的亲缘关系树状图。所有类型的品种在大约0. 45 - 0. 80 的距离水平被聚在一起, 并于近 0. 57 处分成 5 簇。其中野大豆 01 - 336 居群与栽培种黑农 40 单独成簇 ,与其它品种间的亲缘关系最远, 其它野生居群及栽培品种交叉排列 , 分成 8簇。同一簇内野大豆居群间的遗传关系较近 ,与栽培大豆品种间遗传距离较远 ;不同簇间的野生大豆居群亲缘关系较远 ,隔离性强于簇内野生大豆与栽培种。黑农 40 与其它栽培品种亲缘关系较远;农家品种小金黄 11905 与白眉 103亲缘关系很近, 与栽培品种合丰 34、抗线 3、绥农 8 亲缘关系相对近 ;农家品种黄宝珠与元宝金和宝丰 7亲缘关系相对较近。

Abstract:: 　The genetic relationships among 8 populations of Glycinne soja and 20 varieties of G. max fromnortheast of China were analyzed by RAPD method. 141 bands were amplified totally with 9 primers, inwhich 6 bands were homologous , 21 bands were unique and 114 bands were polymorphic respectively. Theresults showed that there were high polymorphic between G. soja andG. max in Northeast of China. Phy-logenetic tree of cultivars was obtained through UPGMA cluster analysis. All cultivars were clustered at0. 45 to 0. 80 distance level , 5 clusters were branched at 0. 57. Wild species(G. soja 01- 336)and cultivar(G. max Heinong 40)were clustered solely from other cultivars, and the rest were crossed and divided to8 clusters again. In the same cluster , the relationships of the wild species were closed and insulated signifi-cantly with cultivars. In the different clusters, the relationships of the wild species were far and the segre-gation was stronger than G. soja and G. max that of the same cluster.

参考文献/References:

1　崔章林, 盖钧镒. 世界大豆研究进展与动向[ J]. 大豆科学, 1995,14(2):167 - 173.

2　惠东威. 利用 RAPD 对大豆属植物系统学研究的初报[ J]. 科学通报, 1994, 39(2):175 - 178.

3　庄炳昌. 中国不同纬度不同进化类型大豆的 RAPD 分析[ J]. 科学通报, 1994, 39 (23):2178 - 2180.

4　邱丽娟. 利用 RAPD 标记鉴定大豆种质[ J] . 作物学报, 1996, 23(4):408- 417.

5　张志永, 盖钧镒. RAPD 在大豆种质资源及遗传连锁中的应用[ J]大豆科学, 1997. 16(1):60- 63.

6　Williams J G K , Kubelik A R, Livak K. J, et al. DNA polymor -phismsam plified by arbitrary primers are use fulas genetic mark-ers[ J]. Nucleic A cid Research, 1990, 18:6531 - 6535.

7　M ailer R J. Discrimination among cultivars of rapeseed (B rassicanapus L.) using DNA polymorphisms amplified from arbitraryprimers[ J]. T heor Appl Genet , 1990, 87:697 - 704.

8　Huff D R. RAPD variation within and among natural populationsof outcrossing buffalograss(Buchloe dactyloides(Nutt.)Engelm.)[ J]. Theor Appl Genet, 1993, 86:927- 934.

9　Mienie C M S. U se of random am plified polymo rphic DNA for i-dentification of South African soybean cultivars[ J] . Field CropsResearch, 1995, 43:43- 49.

10 Vaughan D A. Population genetic diversity of wild soybean on theKantoplain, Japan.[ J] Soy Genet Newsl. , 1995, 22:145- 146.

11 Chen L F O. Polymorphic distinction of soybean by molecularmarkers[ J] . Soy Genet Newsl. , 1994, 21:70 - 75.

12 Terry L. Molecular phy logeny as a tool for soybean breeding Ⅳ[ J] .Soy Genet Newsl. , 1995, 22:251 - 259.

13 Skorupska H T. Resistance to soybean cyst nematode and molecu-lar polymorphism in various sources of Peking soybean[ J] . Eu-phy tica, 1994, 75:63- 70.

14 Vantoai T T. RAPD markers of flooding tolerant Chinese soybeangermplasm[ J] . Soy Genet Newsl. , 1993, 20:153 - 159.

15 Rogers S O , Bendich A J. Extraction of DNA from plant tissues[ M] . Plant Mol Biol Manual, 1988, A6:1 - 10.

16 Lark K G , J. Evans, F. Basha. Molecular Phylogenyasa tool forsoy bean breeding [ J] . Soybean Genetics Newsletter, 1992, 19:174- 181.

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备注/Memo

基金项目:国家高技术研究发展计划(863)编号 2002AA207007;黑龙江省教育厅科学技术研究项目, 编号 10541258

作者简介:郑蔚虹(1961 -), 女, 副教授, 研究方向植物生理与分子生物学。E - mail:zhengweihongl@sina. com

**通讯作者:E - mail:nky ssbd@mail. hl. cn

更新日期/Last Update: 2017-01-08