An analysis of homoeologous microsatellites from Triticum urartu and Triticum monococcum

文献类型: 外文期刊

第一作者: Bai, JR

作者: Bai, JR;Liu, KF;Jia, X;Wang, DW

作者机构:

关键词: Microsatellite;T. urartu;T. monococcum;Wheat;Genetic-linkage map;Simple sequences;Dna markers;Bread wheat;Genome;Amplification;Repeat;Transferability;Arabidopsis;Integration

期刊名称:PLANT SCIENCE ( 影响因子:4.729; 五年影响因子:5.132 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: Compared to hexaploid common wheat (Triticum aestivum, 2n = 6x = 42, AABBDD), little is known about microsatellites and their nucleotide sequences in related diploid wheat species carrying the A(u) or A(m) genomes. We tried to amplify homoeologous microsatellites from Triticum urartu (2n = 2x = 14, A(u)A(u)) and Triticum monococcum (2n = 2x = 14, A(m)A(m)) using 54 sets of PCR primers originally designed for the microsatellites of the A genome of common wheat, and found that 26 primer sets amplified microsatellite products in all seven accessions of T. urartu and all three accessions of T. monococcum. On the basis of the amplification results, the nucleotide sequences of three representative homoeologous microsatellites were amplified from multiple accessions of T. urartu and T. monococcum and compared. The results showed that homoeologous microsatellites from T. urartu and T. monococcum varied in their nucleotide sequences. The patterns of nucleotide sequence variations differed among individual loci, with some showing variations only in the repeat regions or the flanking sequences and others in both the repeat regions and the flanking sequences. Nucleotide sequence variations in the flanking regions were caused by base substitution and/or indel mutations. The variations in the repeat regions involved changes in the repeat number or a combination of repeat number changes and insertions of additional types of dinucleotide sequences

分类号: Q94

  • 相关文献

[1]Phylogeography and origin of sheep breeds in Northern China. Ma, YH,Rao, SQ,Lu, SJ,Hou, GY,Guan, WJ,Li, HB,Li, X,Zhao, QJ,Guo, J.

[2]Development and Application of Genic Simple Sequence Repeat Markers from the Transcriptome of Loquat. Li, Xiaoying,Xu, Hongxia,Chen, Junwei,Feng, Jianjun.

[3]Generation and characterization of 24 novel EST derived microsatellites from tea plant (Camellia sinensis) and cross-species amplification in its closely related species and varieties. Zhao, Li-Ping,Liu, Zhen,Chen, Liang,Yao, Ming-Zhe,Wang, Xin-Chao.

[4]Genetic relationship and genomic in situ hybridization analysis of the three genomes in Triticum aestivum. Li, DY,Zhang, XY,Yang, J,Rao, GY. 2000

[5]Overexpression of TaHSF3 in Transgenic Arabidopsis Enhances Tolerance to Extreme Temperatures. Zhang, Shuangxi,Li, Pansong,Zhang, Gaisheng,Zhang, Shuangxi,Xu, Zhao-Shi,Yang, Le,Chen, Ming,Li, Liancheng,Ma, Youzhi,Zhang, Shuangxi,Wei, Yiqin.

[6]Genetic diversity and core collection evaluations in common wheat germplasm from the Northwestern Spring Wheat Region in China. Hao, CY,Zhang, XY,Wang, LF,Dong, YS,Shang, XW,Jia, JZ. 2006

[7]Microsatellite markers linked to 2 powdery mildew resistance genes introgressed from Triticum carthlicum accession PS5 into common wheat. Zhu, ZD,Zhou, RH,Kong, XY,Dong, YC,Jia, JZ. 2005

[8]Genetic evidence of local adaptation of wheat yellow rust (Puccinia striiformis f. sp tritici) within France. Duan, X,Leconte, M,Hovmoller, MS,De Vallavieille-Pope, C.

[9]Genome-wide identification and resistance expression analysis of the NBS gene family in Triticum urartu. Liu, Jing,Qiao, Linyi,Qiao, Linyi,Zhang, Xiaojun,Li, Xin,Zhan, Haixian,Guo, Huijuan,Zheng, Jun,Chang, Zhijian.

[10]Utilisation of wild canes from China. Fan, Y-H.,Li, Q-W.,Deng, H-H.. 2011

[11]Molecular mapping of MS-cd1 gene in Chinese kale. Wu, Jian,Zhang, Hui,Fang, Zhi-yuan,Wang, Xiao-wu,Zhang, Xin-mei,Guo, Ai-guang,Ma, Yuan. 2010

[12]Allocation of a powdery mildew resistance locus to the chromosome arm 6RL of Secale cereale L. cv. 'Jingzhouheimai'. Wang, Dan,Zhuang, Lifang,Sun, Ling,Feng, Yigao,Qi, Zengjun,Pei, Ziyou.

[13]Use of mitochondrial RNA genes for the differentiation of four Trichinella species by multiplex PCR amplification. Blaga, R.,Fu, BaoQuan,Le Rhun, D.,Le Naour, E.,Heckman, A.,Zocevic, A.,Boireau, P.,Liu, MingYuan.

[14]Amplifying long transcripts of ryanodine receptors of five agricultural pests by transcriptome analysis and gap filling. Shahzad, Muhammad Faisal,Zhang, Lan,Li, Fei,Liu, Yonglei,Shahzad, Muhammad Faisal,Lin, Kejian.

[15]Comparative Genomic Analysis Reveals Multiple Long Terminal Repeats, Lineage-Specific Amplification, and Frequent Interelement Recombination for Cassandra Retrotransposon in Pear (Pyrus bretschneideri Rehd.). Yin, Hao,Li, Leiting,Jin, Cong,Fan, Lian,Li, Meng,Wu, Jun,Zhang, Shaoling,Du, Jianchang. 2014

[16]Molecular characterization of a novel adult diarrhoea rotavirus strain J19 isolated in China and its significance for the evolution and origin of group B rotaviruses. Ji, Shaozhong,Tang, Qing,Cui, Xiaoying,Yan, Hongyang,Kan, Biao,Gao, Shouyi,Jiang, Shengjun.

[17]Association between expression of reproductive seasonality and alleles of melatonin receptor 1A in goats. Chu, M. X.,He, Y. Q.,Cheng, D. X.,Ye, S. C.,Fang, L.,Wang, J. Y..

[18]The first report of an iridovirus-like agent infection in fanned turbot, Scophthalmus maximus, in China. Shi, CY,Wang, YG,Yang, SL,Huang, J,Wang, QY.

[19]Characterization and development of chloroplast microsatellite markers for Gossypium hirsutum, and cross-species amplification in other Gossypium species. Cai, X. Y.,Liu, F.,Zhou, Z. L.,Wang, X. X.,Wang, C. Y.,Wang, Y. H.,Wang, K. B.. 2015

[20]A case study on the genetic origin of the high oleic acid trait through FAD2-1 DNA sequence variation in safflower (Carthamus tinctorius L.). Sara Rapson,Man Wu,Shoko Okada,Alpana Das,Pushkar Shrestha,Xue-Rong Zhou,Craig Wood,Allan Green,Surinder Singh,Qing Liu. 2015

作者其他论文 更多>>

微信小程序