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利用大型玉米-大刍草回交群体对驯化位点进行连锁作图

Linkage mapping of domestication loci in a large maize teosinte backcross resource.

作者信息

Briggs William H, McMullen Michael D, Gaut Brandon S, Doebley John

机构信息

Laboratory of Genetics, University of Wisconsin, Madison, Wisconsin 53706, USA.

出版信息

Genetics. 2007 Nov;177(3):1915-28. doi: 10.1534/genetics.107.076497. Epub 2007 Oct 18.

DOI:10.1534/genetics.107.076497
PMID:17947434
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2147989/
Abstract

An ultimate objective of QTL mapping is cloning genes responsible for quantitative traits. However, projects seldom go beyond segments <5 cM without subsequent breeding and genotyping lines to identify additional crossovers in a genomic region of interest. We report on a QTL analysis performed as a preliminary step in the development of a resource for map-based cloning of domestication and improvement genes in corn. A large backcross (BC)1 population derived from a cross between maize (Zea mays ssp. mays) and teosinte (ssp. parviglumis) was grown for the analysis. A total of 1749 progenies were genotyped for 304 markers and measured for 22 morphological traits. The results are in agreement with earlier studies showing a small number of genomic regions having greater impact on the morphological traits distinguishing maize and teosinte. Despite considerable power to detect epistasis, few QTL interactions were identified. To create a permanent resource, seed of BC1 plants was archived and 1000 BC2S6 BC1-derived lines are in development for fine mapping and cloning. The identification of four BC1 progeny with crossovers in a single gene, tb1, indicated that enough derived lines already exist to clone many QTL without the need to generate and identify additional crossovers.

摘要

数量性状位点(QTL)定位的一个最终目标是克隆负责数量性状的基因。然而,在没有后续育种和基因分型系以识别感兴趣基因组区域中额外交叉的情况下,项目很少能超越小于5厘摩(cM)的片段。我们报告了一项QTL分析,该分析作为玉米驯化和改良基因基于图谱克隆资源开发的初步步骤。种植了一个由玉米(Zea mays ssp. mays)和大刍草(ssp. parviglumis)杂交产生的大型回交(BC)1群体用于分析。对总共1749个后代进行了304个标记的基因分型,并测量了22个形态性状。结果与早期研究一致,表明少数基因组区域对区分玉米和大刍草的形态性状有更大影响。尽管有相当大的能力检测上位性,但几乎没有鉴定出QTL相互作用。为了创建一个永久性资源,BC1植株的种子被存档,并且正在培育1000个源自BC1的BC2S6品系用于精细定位和克隆。在单个基因tb1中鉴定出四个具有交叉的BC1后代,这表明已经存在足够的衍生系来克隆许多QTL,而无需产生和识别额外的交叉。

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