基于表型、同工酶和分子标记从三个不同来源提取的染色体构建芸薹属 B 基因组基因图谱组。

Construction of Brassica B genome synteny groups based on chromosomes extracted from three different sources by phenotypic, isozyme and molecular markers.

机构信息

Institute of Plant Genetics and Crop Plant Research (IPK), Corrensstr. 3, D-06466, Gatersleben, Germany.

出版信息

Theor Appl Genet. 1996 Nov;93(7):1026-32. doi: 10.1007/BF00230120.

Abstract

The three B genomes of Brassica contained in B. nigra, B. carinata and B. juncea were dissected by addition in B. napus. Using phenotypic, isozyme and molecular markers we characterized 8 alien B-genome chromosomes from B. nigra and B. carinata and 7 from B. juncea by constructing synteney groups. The alien chromosomes of the three different sources showed extensive intragenomic recombinations that were detected by the presence of the same loci in more than one synteny group but flanked by different markers. In addition, intergenomic recombinations were observed. These were evident in euploid AACC plants of the rapeseed phenotype derived from the addition lines carrying a few markers from the B genome due to translocations and recombinations between non-homoeologous chromosomes. The high plasticity of the Brassica genomes may have been an powerful factor in directing their evolution by hybridization and amphiploidy.

摘要

甘蓝型油菜中包含的黑芥、甘蓝型油菜和芥菜型油菜的三个 B 基因组，通过添加到甘蓝型油菜中进行了剖析。利用表型、同工酶和分子标记，我们通过构建同线性群，对来自黑芥和甘蓝型油菜的 8 条异源 B 基因组染色体和来自芥菜型油菜的 7 条异源 B 基因组染色体进行了表征。三个不同来源的异源染色体表现出广泛的基因组内重组，这是通过在一个以上的同线性群中存在相同的基因座但侧翼标记不同来检测到的。此外，还观察到基因组间重组。这些在由于非同源染色体之间的易位和重组而在携带 B 基因组少数标记的添加系衍生的油菜表型的整倍体 AACC 植物中很明显。白菜型基因组的高可塑性可能是通过杂交和异源多倍体化指导其进化的有力因素。

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基于表型、同工酶和分子标记从三个不同来源提取的染色体构建芸薹属 B 基因组基因图谱组。

Construction of Brassica B genome synteny groups based on chromosomes extracted from three different sources by phenotypic, isozyme and molecular markers.

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