Liu Dexin, Liu Fang, Shan Xiaoru, Zhang Jian, Tang Shiyi, Fang Xiaomei, Liu Xueying, Wang Wenwen, Tan Zhaoyun, Teng Zhonghua, Zhang Zhengsheng, Liu Dajun
Engineering Research Center of South Upland Agriculture, Ministry of Education, Southwest University, Chongqing, 400716, People's Republic of China.
Mol Genet Genomics. 2015 Oct;290(5):1683-700. doi: 10.1007/s00438-015-1027-5. Epub 2015 Mar 22.
Upland cotton plays a critical role not only in the textile industry, but also in the production of important secondary metabolites, such as oil and proteins. Construction of a high-density linkage map and identifying yield and seed trait quantitative trail loci (QTL) are prerequisites for molecular marker-assisted selective breeding projects. Here, we update a high-density upland cotton genetic map from recombinant inbred lines. A total of 25,313 SSR primer pairs were screened for polymorphism between Yumian 1 and T586, and 1712 SSR primer pairs were used to genotype the mapping population and construct a map. An additional 1166 loci have been added to our previously published map with 509 SSR markers. The updated genetic map spans a total recombinant length of 3338.2 cM and contains 1675 SSR loci and nine morphological markers, with an average interval of 1.98 cM between adjacent markers. Green lint (Lg) mapped on chromosome 15 in a previous report is mapped in an interval of 2.6 cM on chromosome 21. Based on the map and phenotypic data from multiple environments, 79 lint percentage and seed nutrient trait QTL are detected. These include 8 lint percentage, 13 crude protein, 15 crude oil, 8 linoleic, 10 oleic, 13 palmitic, and 12 stearic acid content QTL. They explain 3.5-62.7 % of the phenotypic variation observed. Four morphological markers identified have a major impact on lint percentage and cottonseed nutrients traits. In this study, our genetic map provides new sights into the tetraploid cotton genome. Furthermore, the stable QTL and morphological markers could be used for fine-mapping and map-based cloning.
陆地棉不仅在纺织工业中起着关键作用,而且在重要次生代谢产物(如油脂和蛋白质)的生产中也发挥着重要作用。构建高密度连锁图谱并鉴定产量和种子性状的数量性状位点(QTL)是分子标记辅助选择育种项目的前提条件。在此,我们更新了一个基于重组自交系的陆地棉高密度遗传图谱。共筛选了25313对SSR引物对,以检测渝棉1号和T586之间的多态性,并使用1712对SSR引物对来对作图群体进行基因分型并构建图谱。在我们之前发表的包含509个SSR标记的图谱基础上,又增加了1166个位点。更新后的遗传图谱的重组总长度为3338.2厘摩,包含1675个SSR位点和9个形态学标记,相邻标记之间的平均间隔为1.98厘摩。之前报道中定位在第15号染色体上的绿色棉绒(Lg)现在定位在第21号染色体上2.6厘摩的区间内。基于该图谱和多个环境下的表型数据,检测到79个皮棉百分率和种子营养性状QTL。其中包括8个皮棉百分率、13个粗蛋白、15个粗脂肪、8个亚油酸、10个油酸、13个棕榈酸和12个硬脂酸含量QTL。它们解释了所观察到的3.5%至62.7%的表型变异。鉴定出的4个形态学标记对皮棉百分率和棉籽营养性状有重大影响。在本研究中,我们的遗传图谱为四倍体棉花基因组提供了新的见解。此外,稳定的QTL和形态学标记可用于精细定位和图位克隆。
