Kwon Soo-Jin, Kim Dong-Hyun, Lim Myung-Ho, Long Yan, Meng Jin-Ling, Lim Ki-Byung, Kim Jin-A, Kim Jung Sun, Jin Mina, Kim Ho-Il, Ahn Sang-Nag, Wessler Susan R, Yang Tae-Jin, Park Beom-Seok
Brassica Genomics Team, National Institute of Agricultural Biotechnology, RDA, Suwon, 441-707, South Korea.
Mol Genet Genomics. 2007 Oct;278(4):361-70. doi: 10.1007/s00438-007-0249-6. Epub 2007 Aug 10.
We have developed a display system using a unique sequence of terminal repeat retrotransposon in miniature (TRIM) elements, which were recently identified from gene-rich regions of Brassica rapa. The technique, named TRIM display, is based on modification of the AFLP technique using an adapter primer for the restriction fragments of BfaI and a primer derived from conserved terminal repeat sequences of TRIM elements, Br1 and Br2. TRIM display using genomic DNA produced 50-70 bands ranging from 100 to 700 bp in all the species of the family Brassicaceae. TRIM display using B. rapa cDNA produced about 20 bands. Sequences of 11 randomly selected bands, 7 from genomic DNA and 4 from cDNA, begin with about 104 bp of the terminal repeat sequences of TRIM elements Br1 or Br2 and end with unique sequences indicating that all bands are derived from unique insertion sites of TRIM elements. Furthermore, 7 of the 11 unique sequences showed significant similarity with expressed gene. Most of the TRIM display bands were polymorphic between genera and about 55% (132 of 239 bands) are polymorphic among 19 commercial F1 hybrid cultivars. Analysis of phylogenetic relationships shows clear-cut lineage among the 19 cultivars. Furthermore, a combination of 11 polymorphic bands derived from only one primer combination can clearly distinguish one cultivar from the others. TRIM display bands were reproducible and inheritable through successive generations that is revealed by genetic mapping of 6 out of 27 polymorphic TRIM markers on the genetic map of Brassica napus. Collective data provide evidence that TRIM display can provide useful DNA markers in Brassica relatives because these markers are distributed in gene-rich regions, and are sometimes involved in the restructuring of genes.
我们开发了一种显示系统,该系统使用了微型末端重复反转录转座子(TRIM)元件的独特序列,这些元件最近从白菜型油菜的基因丰富区域中鉴定出来。这项技术名为TRIM显示,它基于对AFLP技术的改进,使用针对BfaI限制性片段的接头引物和源自TRIM元件Br1和Br2保守末端重复序列的引物。使用基因组DNA的TRIM显示在十字花科的所有物种中产生了50 - 70条带,大小从100到700 bp不等。使用白菜型油菜cDNA的TRIM显示产生了约20条带。随机选择的11条带的序列,7条来自基因组DNA,4条来自cDNA,起始于TRIM元件Br1或Br2末端重复序列的约104 bp,末尾是独特序列,表明所有条带均源自TRIM元件的独特插入位点。此外,11个独特序列中的7个与表达基因显示出显著相似性。大多数TRIM显示条带在属间具有多态性,并且在19个商业F1杂交品种中约55%(239条带中的132条)具有多态性。系统发育关系分析显示19个品种之间有明显的谱系。此外,仅由一种引物组合产生的11条多态性条带的组合可以清楚地将一个品种与其他品种区分开来。TRIM显示条带具有可重复性并且可以通过连续世代遗传,这通过在甘蓝型油菜遗传图谱上对27个多态性TRIM标记中的6个进行遗传定位得以揭示。综合数据提供了证据,表明TRIM显示可以在芸苔属近缘种中提供有用的DNA标记,因为这些标记分布在基因丰富区域,并且有时参与基因重组。
