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Acta Agron Sin ›› 2009, Vol. 35 ›› Issue (5): 958-961.doi: 10.3724/SP.J.1006.2009.00958

• RESEARCH NOTES • Previous Articles     Next Articles

Mapping Unequal Crossing Over Hotspot Region of Simple sequence Repeat in Maize

TANG Ji-Hua12,MA Xi-Qing1,TENG Wen-Tao1,YAN Jian-Bing1,DAI Jing-Rui1,LI Jian-Sheng1*   

  1. 1National Maize Improvement Center of China,China Agricultural University,Beijing 100193,China;2College of Agronmy.Hernan Agricultural University,Zhengzhou 450002,China
  • Received:2008-09-19 Revised:2008-12-15 Online:2009-05-12 Published:2009-02-16
  • Contact: LI Jian-Sheng E-mail:lijiansheng@cau.edu.cn

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Abstract:

The polymorphism of simple sequence repeat (SSR) in biological genome is one result of unequal crossing over for homologous chromosomes; therefore it has theoretical importance in clarifying the hotspot regions of unequal crossing over. A set of recombinant inbred lines (RILs) population that derived form an elite hybrid Yuyu 22 was used in this study, its genetic components of the population was analyzed by means of SSR analysis, and 40 unequal crossing over SSR markers were found. The frequency of the unequal crossing over in the RIL population was 0.34–14.63%, with 10-2–10-1 frequency per generation, and the (AG)n repeat SSR markers accounted for 58.3%. There were 31 unequal crossing over markers locating on 11 chromosomal hotspot regions, distributing on 10 chromosomes except for chromosome 9, including two unequal crossing over hotspot regions each in chromosomes 3 and 5.

Key words: Maize, Simple sequence repeat(SSR), Unequal crossing over, Hotspot region

[1] Civardi L, Xia Y, Edwards K J, Schnable P S, Nikolau B J. The relationship between genetic and physical distances in the cloned a1-sh2 interval of the Zea mays L. genome. Proc Natl Acad Sci USA, 1994, 91: 8268–8272
[2] Sturtevant A H. The effects of unequal crossing over at the bar locus in Drosophila. Genetics, 1925, 10: 117–147
[3] Sturtevant A H, Morgan T H. Reverse mutation of the bar gene correlated with crossing over. Science, 1923, 57: 746–747
[4] Tusié-Luna M T, White P C. Gene conversions and unequal crossovers between CYP21 (steroid 21-hydroxylase gene) and CYP21P involve different mechanisms. Proc Natl Acad Sci USA, 1995, 92: 10796–10800
[5] Baumer A, Dutly F, Balmer D, Riegel M, Tükel T, Krajewska-Walasek M, Schinzel A A. High level of unequal meiotic crossovers at the origin of the 22q11.2 and 7q11.23 deletions. Human Mol Genet, 1998, 7: 887–894
[6] Webb C A, Richter T E, Collins N C, Nicolas M, Trick H N, Pryor T, Hulbert. Genetic and molecular characterization of the maize rp3 rust resistance locus. Genetics, 2002, 162: 381–394
[7] Collins N, Drake J, Ayliffe M, Sun Q, Ellis J, Hulbert S, Pryor T. Molecular characterization of the maize Rp1-D rust resistance haplotype and its mutants. Plant Cell, 1999, 11: 1365–1376
[8] Silver L M, White M, Artzt K. Evidence for unequal crossing over within the mouse T/t complex. Proc Natl Acad Sci USA, 1980, 77: 6077–6080
[9] Adams K L, Wendel J F. Polyploidy and genome evolution in plants. Curr Opin Plant Biol, 2005, 8: 135–141
[10] Lockton S, Gaut B S. Plant conserved non-coding sequences and paralogue evolution. Trends Genet, 2005, 21: 60–65
[11] Zhang L, Gaut B S. Does recombination shape the distribution and evolution of tandemly arrayed genes (TAGs) in the Arabidopsis thaliana genome? Genome Res, 2003, 13: 2533–2540
[12] Goodfellow P N. Variation in now the theme. Nature, 1992, 359: 777–778
[13] Powell W, Machray G C, Provan J. Polymorphism revealed by simple sequence repeats. Trends Plant Sci, 1996, 1: 215–222
[14] Jeffreys A J, Wilson V, Thein S L. Hypervariable “minisatellite” regions in human DNA. Nature, 1985, 314: 67–73
[15] Crow J F, William F D. Anecdotal, historical and critical commentaries on genetics: unequal crossing over then and now. Genetics, 1988, 120: 1–6
[16] Walsh J B. Persistence of tandem arrays: implications for satellite and simple-sequence DNAs. Genetics, 1987, 115: 553–567
[17] Sia E A, Jinks-Robertson S, Petes T. Genetic control of microsatellite stability. Mutat Res, 1997, 383: 61–70
[18] Saghai-Maroof M A, Soliman K M, Jorgensen R A, Allard R W. Ribosomal DNA spacer length polymorphisms in barley: Mendelian inheritance, chromosomal location, and population, and population dynamics. Proc Natl Acad Sci USA, 1984, 81: 8014–8018
[19] Lincoln S, Daly M, Lander E. Mapping genetic mapping with MAPMAKER/EXP3.0. Cambridge: Whitehead Institute Technical Report, 1992
[20] Yan J-B(严建兵), Tang H(汤华), Huang Y-Q(黄益勤), Zheng Y-L(郑用琏), Li J-S(李建生). Genetic analysis of segregation distortion of molecular markers in maize F2 population. Acta Genet Sin (遗传学报), 2003, 30(10): 913–918 (in Chinese with English abstract)
[21] Tang J H, Ma X Q, Yan J B, Teng W T, Wu W R, Dai J R, Li J S. The QTL and heterotic detection loci for plant height using an immortalized F2 population in maize. Chin Sci Bull, 2007, 51(24): 2864–2869
[22] Udupa S M, Robertson L D, Weigand F, Baum M, Kahl G. Allelic variation at (TAA)n microsatellite loci in a world collection of chickpea (Cicer arietinum L.) germplasm. Mol Gen Genet, 1999, 261: 354–363
[23] Schug M D, Mackay T F C, Aquadro C F. Low mutation rates of microsatellite loci in Drosophila lanogaster. Nat Genet, 1997, 15: 99–102
[24] Xu X, Peng M, Fang Z, Xu X. The direction of microsatellite mutations is dependent upon the allele length. Nat Genet, 2000, 24: 396–399
[25] Eisen J A. Mechanistic basis for microsatellite instability. In: Goldstein D B, Schl?tterer C, eds. Microsatellites—evolution and applications. Oxford: Oxford University Press, 1999. pp 34–48
[26] Kermicle J K, Eggleston W B, Alleman M. Organization of paramutagenicity in R-stipples maize. Genetics, 1995, 141: 361–372
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