精细定位番茄碳同位素组成的一个数量性状基因座

Fine mapping a QTL for carbon isotope composition in tomato.

作者信息

Xu Xiangyang, Martin Bjorn, Comstock Jonathan P, Vision Todd J, Tauer Charles G, Zhao Baige, Pausch Roman C, Knapp Steven

机构信息

Department of Plant and Soil Sciences, Oklahoma State University, Stillwater, OK 74078, USA.

出版信息

Theor Appl Genet. 2008 Jul;117(2):221-33. doi: 10.1007/s00122-008-0767-6. Epub 2008 Apr 30.

DOI:10.1007/s00122-008-0767-6

PMID:18542914

Abstract

Carbon isotope composition (delta(13)C) and leaf water-use efficiency vary in concert in C3 plants, making delta(13)C useful as a proxy for plant water-use efficiency. A QTL for delta(13)C was detected in the Solanum pennellii chromosome fragment of IL5-4, an introgression line with S. lycopersicum cv. M82 background. M82 and IL 5-4 were crossed, and RFLP markers in the target region converted to PCR-based markers. Forty-one recombinants with an introgression fragment ranging in length from 1.1 to 11.4 cM were identified by marker assisted selection (MAS) among approximately 2000 F2 plants. A total of 29 markers were mapped within the introgression fragment unique to IL5-4. These markers divided the about 9 cM target region into nine intervals. A dominant QTL for delta(13)C, designated QWUE5.1 that explained 25.6% of the total phenotypic variance was mapped to an interval about 2.2 cM long. Twenty-one plants with a S. pennellii chromosome fragment shortened to a length of 2.0-9.1 cM by a second recombination event were generated by MAS of 1,125 F4 plants. Two near isogenic lines with high delta(13)C (small negative value) and carrying QWUE5.1 on the shortest introgression fragments (about 7.0 cM) were identified. The markers and genetic stocks developed are valuable for cloning the gene underlying QWUE5.1, MAS of QWUE5.1, and fine-mapping genes/QTL located in this region.

摘要

在C3植物中，碳同位素组成（δ(13)C）和叶片水分利用效率协同变化，这使得δ(13)C可作为植物水分利用效率的一个替代指标。在IL5 - 4的茄属彭奈利染色体片段中检测到一个与δ(13)C相关的数量性状基因座（QTL），IL5 - 4是一个以番茄栽培品种M82为背景的渐渗系。将M82和IL 5 - 4杂交，并将目标区域中的限制性片段长度多态性（RFLP）标记转化为基于聚合酶链反应（PCR）的标记。通过标记辅助选择（MAS）在大约2000株F2植株中鉴定出41个重组体，其渐渗片段长度在1.1至11.4厘摩（cM）之间。共有29个标记定位在IL5 - 4特有的渐渗片段内。这些标记将约9 cM的目标区域划分为9个区间。一个控制δ(13)C的显性QTL，命名为QWUE5.1，解释了25.6%的总表型变异，该QTL被定位到一个约2.2 cM长의区间。通过对1125株F4植株进行MAS，获得了21株由于第二次重组事件而使茄属彭奈利染色体片段缩短至2.0 - 9.1 cM长度的植株。鉴定出两个δ(13)C值高（小的负值）且在最短渐渗片段（约7.0 cM）上携带QWUE5.1的近等基因系。所开发的标记和遗传材料对于克隆QWUE5.1基因、QWUE5.1的MAS以及对该区域内的基因/QTL进行精细定位具有重要价值。

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精细定位番茄碳同位素组成的一个数量性状基因座

Fine mapping a QTL for carbon isotope composition in tomato.

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