PCR-SSCP技术与比较基因组学结合定位棉花Li1基因

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摘要聚合酶链式反应-单链构象多态性(polymerase chain reaction-single strand conformation polymorphism, PCR-SSCP)作为一种能检测基因组间DNA碱基微小差异的技术手段，具有操作简便、快捷且灵敏度高等优点。比较基因组学近年来已经成为研究生物基因组的最主要手段之一；大量基因组序列的产生为通过比较基因组学开发新标记和定位目标基因提供了大量的DNA序列资源。本研究以李氏超短纤维突变体(Ligon lintless-1, Li1)为材料，定位Li1基因，针对PCR扩增产物片段较大的样品(＞400 bp)进行PCR-SSCP技术的优化，用已发表的拟南芥(Arabidopsis thaliana)和棉花(Gossypium spp.) D基因组DNA序列为参考，探索PCR-SSCP技术与比较基因组学结合开发新标记应用于棉花基因定位的可能性。结果表明，电压为150 V，胶浓度为10%，电泳温度为4 ℃时电泳结果最好；上样缓冲液与PCR扩增目的片段比例为5∶1为最佳比例。利用上述优化的PCR-SSCP技术将根据棉花与拟南芥同线性区段开发的分子标记构建了一个由28个标记组成的长度为149.6 cM的遗传图，该区域包含4个功能上与Li1位点密切相关的基因。此外，利用D基因组序列开发的标记构建了一个由17个SSCP标记和Li1位点组成，跨越40.3 cM的遗传图谱，距其最近的两端标记W058和P095分别为0.6 和0.3 cM。本研究为棉花Li1基因的精细定位及其候选基因的克隆提供了理论基础。

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	杨芬
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	蒋玉蓉

关键词 ：棉花, 分子标记, PCR-SSCP, 李氏超短纤维突变体(Li1), 比较基因组学, 遗传作图

Abstract：Polymerase chain reaction-single strand conformation ploymorphism (PCR-SSCP), as an important technique in detecting minor differences between genomic DNA bases, has the characteristics of simplicity, rapidity and sensitivity. So far, a large number of genome sequences provide lots of DNA sequences for the development of novel genetic markers through comparative genomics and the mapping of target genes. Hence, the possibility was investigated on the application of PCR-SSCP technique combined with comparative genomics to develop novel molecular markers in cotton (Gossypium spp.) genetic mapping in the study, taking Ligon lintless-1 (Li1) mutant gene mapping as an example and the published sequences of Arabidopsis and cotton genome D as references. The optimization of SSCP conditions for samples of large fragment PCR products (＞400 bp) were carried out in the experiment. The results showed that the optimal experiment conditions were as follows: voltage of 150 V, gel concentration of 10%, electrophoresis temperature of 4 ℃, and 5∶1 of loading dye to PCR product. According to the linear segments of Arabidopsis and cotton, we selected 102 cotton EST sequences to develop the SSCP primers. The optimized PCR-SSCP system was utilized to construct a genetic map consisting of 28 markers and spanning 149.6 cM . This genetic map contained 4 genes with functions closely related to Li1 loci. Additionally, using genome D sequences, 185 SSCP primers were developed and there were 86 primers showing polymorphism between the two parents (Li1 and H7124). In this experiment, Li1 gene was firstly mapped in a genetic map consisting of 17 SSCP markers and the Li1 loci, which spanned 40.3 cM. The Li1 gene was flanked by W058 and P095, which were the nearest markers, and the distance from Li1 loci was 0.6 and 0.3 cM respectively. Using the published Li1 genetic map to analyze the relationship between D genome sequences and two genetic maps constructed in this experiment, the study suggested that there were good homologous between these genetic maps. The results presented here could offer a useful foundation for future research work on fine mapping and cloning of Li1 gene. In addition, with the development of the third generation genome sequencing technology, constantly enrichment of the GenBank and the publishment of cDNA sequences, the optimization of SSCP technology plays an important role in cotton genetic linkage map construction, map-based cloning, molecular marker-assisted breeding and other aspects.

Key words： Cotton Molecular markers PCR-SSCP Ligon lintless-1( Li1) Comparative genomics Genetic mapping

收稿日期: 2015-09-17 出版日期: 2016-02-24

基金资助:国家自然科学基金资助项目;农业部转基因生物新品种培育重大专项;棉花生物学国家重点实验室开放项目

通讯作者: 蒋玉蓉 E-mail: yurongjiang746@126.com

引用本文:

杨芬曹跃芬代华琴蒋玉蓉. PCR-SSCP技术与比较基因组学结合定位棉花Li1基因[J]. , 2016, 24(4): 613-624.

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http://journal05.magtech.org.cn/Jwk_ny/CN/ 或 http://journal05.magtech.org.cn/Jwk_ny/CN/Y2016/V24/I4/613

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