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作物学报 ›› 2007, Vol. 33 ›› Issue (01): 97-101.

• 研究论文 • 上一篇    下一篇

水稻Ds插入双分蘖突变体形成机理的分析

孙丙耀1;顾福根1;袁云香1;谈建中2;万志刚1;陆小平2   

  1. 1苏州大学生命科学学院;2苏州大学城市科学学院,江苏苏州 215123
  • 收稿日期:2006-05-09 修回日期:1900-01-01 出版日期:2007-01-12 网络出版日期:2007-01-12
  • 通讯作者: 孙丙耀

Analysis of the Generation Mechanism of a Ds-inserted Rice Mutant with Double Tillers at One Tillering Node

SUN Bing-Yao1,GU Fu-Gen1,YUAN Yun-Xiang1,TAN Jian-Zhong2,WAN Zhi-Gang1,LU Xiao-Ping2   

  1. 1 School of Life Sciences, Suzhou University; 2 School of Urbanology, Suzhou University, Suzhou 215123, Jiangsu, China
  • Received:2006-05-09 Revised:1900-01-01 Published:2007-01-12 Published online:2007-01-12
  • Contact: SUN Bing-Yao

摘要:

在水稻Ds插入突变株筛选过程中,发现一个在同一分蘖节形成大、小两个分蘖的双分蘖突变体dt1(double tillers mutant),两个分蘖均可正常抽穗形成有效分蘖。采用TAIL-PCR技术从该突变体中克隆了Ds插入的侧翼序列,将该序列作为查询序列进行核苷酸序列数据库(NCBI-BLAST)在线比对分析,发现所克隆的Ds侧翼序列与3号染色体的克隆OJ1345H02(gi|21281466)序列同一性达100%。以FGENESH和GeneMark.hmm两种软件分别对Ds插入基因的结构进行分析,在外显子的数目、大小、位置等方面均得出高度一致的结果。同时,用NCBI Entrez server和Pfam等软件对该基因进行功能预测,推测的基因编码产物含保守的FH2结构域,为水稻类形成素蛋白。突变体后代Ds插入基因型分析显示,其后代出现分离,表明该突变体为Ds插入杂合体。

关键词: 水稻, Ds插入突变, 分蘖突变体

Abstract:

Insertion mutagenesis with T-DNA or transposable elements is currently one of the most powerful tools for screening various types of mutations in higher plants, and for analyzing functional information of genes related to those mutations. By using the Ac/Ds transposable elements system in rice, a great deal of Ds-inserted mutants may be efficiently generated, and used for functional identification of genes that influence important agronomic traits, by which the researches in rice functional genomics have been greatly promoted. As a key agronomic trait related to grain production in rice and other grass species and an important property parallel to branching in dicotyledonous plants, tillering in rice has attracted more research interests. In the present study, a rice tillering mutant was isolated from a collection of Ds-inserted mutant lines, and was designated dt1 (double tillers mutant) according to its tillering phenotype of a major tiller and a minor tiller developed at the same tillering node. Both tillers were found to be productive with the ears normally emerged from each of them. The Ds-flanking sequence was cloned from this mutant by using TAIL-PCR amplification technique. The sequenced Ds-flanking sequence was used as a query to perform an online search for homologous sequence against nucleotide sequence database by NCBI-BLAST, the results indicated that the Ds-flanking sequence showed 100% identity at the nucleotide level to the sequence of clone OJ1345H02 (gi|21281466) of rice chromosome 3. The structure of the Ds-inserted gene was predicted by using software of FGENESH and GeneMark, respectively, and gotten highly similar in the number, size and location of exons within the gene. The results also showed that the Ds element was inserted into the region between transcription start site and the first exon, at 173 bp upstream of the first exon. Moreover, the product encoded by the gene was predicted by NCBI Entrez server and Pfam. It was revealed that the deduced product was a rice formin-like protein containing a highly conserved FH2-domain. Given the fact that the Ds element as big as 5.9 kb in size was inserted immediately into upstream of the first exon, it is suggested that Ds insertion probably make the gene loss it’s function, and thereby generate the rice mutant dt1. In addition, the genotyping for Ds insertion in the progeny plants of dt1 mutant indicated that these progeny plants segregated into homozygous and heterozygous types for Ds insertion and Ds free plants, which suggested that the dt1 mutant was heterozygous for Ds insertion.

Key words: Oryza sativa L., Ds insertion mutagenesis, Tillering mutant

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