Genetic diversity of melon landraces (Cucumis melo L.) in the Xinjiang Uygur Autonomous Region on the basis of simple sequence repeat markers

文献类型: 外文期刊

第一作者: Zhang, Yongbing

作者: Zhang, Yongbing;Aierken, Yasheng;Ma, Xinli;Yi, Hongping;Wu, Mingzhu;Fan, Xiangbin

作者机构:

关键词: Cucumis melo;Genetic diversity;Landraces;Xinjiang Uygur Autonomous Region;Simple sequence repeat markers

期刊名称:GENETIC RESOURCES AND CROP EVOLUTION ( 影响因子:1.524; 五年影响因子:1.713 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: We investigated the genetic variation and relationships among 35 melon landraces collected from the Xinjiang Uygur Autonomous Region in northwestern China by using 19 polymorphic simple sequence repeat markers (SSRs). A total of 55 polymorphic alleles were amplified. The number of alleles per SSR locus ranged from 2 to 5 with an average of 2.89 alleles per locus. The average gene diversity (GD) was 0.42 with a range of 0.06-0.71, and the average observed heterozygosity was 0.22 with a range of 0.06-0.97, indicating that the genetic diversity among the Xinjiang melon landraces was abundant. Genetic variation was also detected between the landrace populations in different regions in Xinjiang. The most abundant genetic diversity was observed among the landraces in Eastern Xinjiang, with the highest GD of 0.45 and PIC of 0.39. Eleven alleles (20 %) were found exclusively in the landraces from Eastern Xinjiang, and two alleles (3.6 %) were unique to the landraces from Southern and Northern Xinjiang. The genetic similarity matrix was defined on the basis of Jaccard coefficient to determine the genetic relationships among Xinjiang landraces. Cluster analysis was performed using the unweighted pair group method with arithmetic means, showing that the 'wild Hami' (XJ-34) landrace was distinct from the 34 other landraces that were divided into three clusters. Therefore, the genetic background of XJ-34 differed from that of the other landraces. The landraces were not precisely separated on the basis of their geographic origins, although most of these landraces were likely grouped near one another, as visualized through principal coordinate analysis. Thus, western China is one of the primary or secondary centers of melon diversity because of the relatively higher genetic variation detected among Xinjiang landraces. Except the 'wild Hami' landrace, Xinjiang melon landraces could be classified into two botanical varieties, namely, var. inodorus and var. cantalupensis. However, the distinction between these two genotypes was not significantly different.

分类号: S18

  • 相关文献

[1]DEVELOPMENT AND CHARACTERIZATION OF 21 EST-DERIVED MICROSATELLITE MARKERS IN VICIA FABA (FAVA BEAN). Ma, Yu,Yang, Tao,Guan, Jianping,Wang, Shumin,Wang, Haifei,Sun, Xuelian,Zong, Xuxiao.

[2]Genetic diversity and relationship of global faba bean (Vicia faba L.) germplasm revealed by ISSR markers. Wang, Hai-fei,Zong, Xu-xiao,Guan, Jian-ping,Yang, Tao,Sun, Xue-lian,Ma, Yu,Redden, Robert. 2012

[3]Analysis of genetic diversity among indigenous landraces from sesame (Sesamum indicum L.) core collection in China as revealed by SRAP and SSR markers. Zhang, Yan-xin,Zhang, Xiu-rong,Hua, Wei,Wang, Lin-han,Che, Zhuo. 2010

[4]Genetic diversity and relationships among cabbage (Brassica oleracea var. capitata) landraces in China revealed by AFLP markers. Kang, Jungen,Fang, Zhiyuan,Wang, Xiaowu,Xu, Donghui,Liu, Yumei,Yang, Limei,Zhuang, Mu,Zhang, Yangyong,Kang, Jungen. 2011

[5]POPULATION STRUCTURE AND GENETIC DIVERSITY OF MAIZE LANDRACES FROM THE SOUTHWEST MAIZE REGION OF CHINA. Liu, Z. Z.,Guo, R. H.,Wang, R. H.,Shi, Y. S.,Song, Y. C.,Wang, T. Y.,Li, Y.,Liu, Z. Z.,Cai, Y. L.,Guo, R. H.,Cao, M. J.,Zhao, J. R.,Wang, F. G.,Wang, R. H.. 2009

[6]Molecular Analysis of the Genetic Diversity of Chinese Hami Melon and Its Relationship to the Melon Germplasm from Central and South Asia. Long, Bo,Long, Chunlin,Aierken, Yasheng,Akashi, Yukari,Phan Thi Phuong Nhi,Halidan, Yikeremu,Nishida, Hidetaka,Kato, Kenji,Aierken, Yasheng,Wu, Min Zhu,Tanaka, Katsunori. 2011

[7]Transcriptomic Identification of Drought-Related Genes and SSR Markers in Sudan Grass Based on RNA-Seq. Wang, Xia,Huang, Linkai,Zhang, Xinquan,Li, Zhou,Yan, Haidong,Zhu, Yongqun,Lin, Chaowen,Xu, Wenzhi,Luo, Fuxiang,Wang, Xie,Yao, Li,Peng, Dandan,Peng, Jianhua. 2017

[8]Mapping QTLs for drought tolerance in an F-2:3 population from an inter-specific cross between Gossypium tomentosum and Gossypium hirsutum. J.Y. Zheng,G. Oluoch,M.K. Riaz Khan,X.X. Wang,X.Y. Cai,Z.L. Zhou,C.Y. Wang,Y.H. Wang,X.Y. Li,F. Liu,K.B. Wang. 2016

[9]De novo assembly and characterization of the root transcriptome and development of simple sequence repeat markers in Paphiopedilum concolor. Li, D. M.,Zhao, C. Y.,Liu, X. R.,Liu, X. F.,Lin, Y. J.,Liu, J. W.,Chen, H. M.,Lu, F. B.. 2015

[10]Replication of pistillate plants of Ricinus communis L. and investigation of the sex stability and genetic variation of the somaclones. Tan, Meilian,Yan, Mingfang,Wang, Lei,Yan, Xingchu,Fu, Chunling,Wang, Lijun. 2013

[11]Mapping QTLs for nitrogen-deficiency tolerance at seedling stage in rice (Oryza sativa L.). Cao, L. Y.,Wu, W. M.,Shen, X. H.,Zhan, X. D.,Zhai, R. R.,Wang, R. C.,Chen, D. B.,Cheng, S. H.,Feng, Y..

[12]A Simple Sequence Repeat Marker Linked to the Susceptibility of Apple to Alternaria Blotch Caused by Alternaria alternata Apple Pathotype. Zhang, Liyi,Cong, Peihua,Li, Ying,Zhang, Zhen,Cheng, Zong-Ming,Cheng, Zong-Ming.

[13]Identification of new Pina null mutations among Asian common wheat cultivars. Ikeda, Tatsuya M.,Takata, Kanenori,Cong, Hua,Suzuki, Takako.

[14]Geographical variation of nuclear genome RFLPs and genetic differentiation in foxtail millet, Setaria italica (L.) P. Beauv.. Fukunaga, K,Wang, ZM,Kato, K,Kawase, M. 2002

[15]PERFORMANCE OF DIVERSE WHEAT GENETIC STOCKS UNDER MOISTURE STRESS CONDITION. Seher, Misbah,Shabbir, Ghulam,Rasheed, Awais,Kazi, Alvina Gul,Mahmood, Tariq,Mujeeb-Kazi, Abdul. 2015

[16]Molecular and biochemical characterization of puroindoline A and B alleles in chinese improved cultivars and landraces. He, Z. H.,Chen, F.,Xia, X. C.,Zhang, X. Y.,He, Z. H.,Lillemo, M.,Morris, C. F.. 2007

[17]Progress in Breeding of Early Mature, Thick Rind Melon in Xinjiang. Wu, Mingzhu,Yi, Hongping,Feng, Jiongxin,Wang, Dengming,Zhang, Yongbing,Wu, Haibo. 2010

[18]Melatonin alleviates cold-induced oxidative damage by regulation of ascorbate-glutathione and proline metabolism in melon seedlings (Cucumis melo L.). Zhang, Y. P.,Chen, Y. Y.,Zhang, Y. P.,Xu, S.,Yang, S. J.,Chen, Y. Y..

[19]Role of leaf structure in resistance to powdery mildew in water melon. Zhang, Hui-Jun,Ge, Yu,Wang, Qiang,Zhang, Jian-Nong.

[20]Breeding disease-resistant Hami-melon. Wu, MZ,Yi, HP,Zhai, WQ,Feng, JX. 2004

作者其他论文 更多>>

微信小程序