小麦-大麦矮秆渗入系WB29的分子细胞学鉴定及其矮秆遗传特性分析

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摘要 WB29是由农家二棱大麦(Hordeum vulgare ssp. distichon Hsü.)与普通小麦(Triticum aestivum L.)7182回交多代选育的矮秆种质，平均株高57 cm，为明确其矮秆性状遗传规律，结合细胞学鉴定、田间株高调查、赤霉素敏感性鉴定和分子标记技术对该种质进行了鉴定。细胞学鉴定结果表明，WB29根尖染色体数为2n=42，用大麦基因组DNA为探针对WB29根尖细胞染色体进行基因组原位杂交(genomic in situ hybridization, GISH)未发现大麦杂交信号；大麦特异序列标签位点(specific sequence-tagged site, STS)标记ABG459(2HS)在WB29中扩增出了大麦特征条带。利用10对小麦矮秆基因(reduced height gene, Rht)标记对农家二棱大麦、7182、WB29和中国春鉴定，结果7182和WB29检测出含有Rht-D1b，而其他材料不携带任何所检测的基因。通过WB29与中国春杂交获得BC1F1和F2分离群体，对这两个分离群体进行统计分析发现WB29的矮秆性状受1对不完全显性基因控制。赤霉素鉴定结果表明，该矮秆种质为赤霉素不敏感型。对F2群体利用引物ABG459进行筛选后鉴定出322株含有与WB29相同的大麦特征条带；同时对F2中Rht-D1b基因进行了检测，发现343株含有该基因。连锁分析结果表明，ABG459与WB29中主效矮秆基因连锁，遗传距离约为7.0 cM，而Rht-D1b与该主效矮秆基因不连锁。以上结果证实，WB29中携带有大麦2HS染色体遗传物质，WB29中矮秆基因可能位于大麦2HS染色体上或其插入位点附近，且该基因对降低WB29的株高起到了一定作用。本研究明确了WB29为小麦-大麦杂种后代，此材料的育成不仅丰富了小麦-大麦中间材料的种质资源，而且该材料中的主效矮秆基因可能来自于大麦，可能为一新的矮源，对丰富矮秆种质资源和扩大小麦育种中矮秆基因的利用范围具有一定意义。

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	昝凯
	郑青焕
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	陈真真
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	刘洋
	王亮明
	刘淑会
	王中华
	陈新宏

关键词 ：小麦, 大麦, 渐渗系, 基因组原位杂交(GISH), 序列标签位点(STS), 矮秆基因, 遗传规律

Abstract：The new germplasm WB29 with an average height of 57 cm was a dwarf line of wheat (Triticum aestivum L.) which was selected from the derived lines after crossing and backcrossing multi-generational between common wheat 7182 and two-rowed barley (Hordeum vulgare ssp. distichon Hsü.). Cytology observation, plants height investigation, gibberellic acid reaction and molecular markers technology were used to identify this material and its heredity of dwarf traits. Cytology identification showed that the chromosome number of root-tip cell was 2n=42, no obvious hybridization signal was observed in genomic in situ hybridization (GISH) with two-rowed barley genomic DNA acted as a probe. Specific sequence-tagged site (STS) markers of barley ABG459 (2HS) could amplify specific bands of barley from WB29. Ten pairs of specific molecular markers for wheat dwarfing genes (reduced height gene, Rht) were applied to identify two-rowed barley, 7182, WB29 and Chinese spring and the result showed that 7182 and WB29 had Rht-D1b while none of the 10 Rht were detected in barley and Chinese spring. BC1F1 and F2 population were derived from crossing between WB29 and Chinese, and the statistical analysis of these two derived population indicated the dwarf traits of WB29 was controlled by one pair of incomplete dominance gene. Gibberellic acid reaction pointed that WB29 was a gibberellic-insensitive type of wheat. STS of barley ABG459 (2HS) was used to evaluate F2 population and 343 plants were found to have the barley 2HS chromosome. Wheat dwarfing gene Rht-D1b in F2 population was also detected and the result showed that 322 plants contained Rht-D1b. Linkage analysis showed that STS marker ABG459 was closely linked to the main dwarfing gene of WB29 at a genetic distance of 7.0 cM, while Rht-D1b was not linked to this main dwarfing gene. The result above had defined that WB29 did contain the barley 2HS chromosome and the dwarfing gene of WB29 which had played an important role in reducing the plant height may be located right in the barley 2HS chromosome sequence or near its insertion site. The conclusion of this research had fixed that WB29 was a wheat-barley hybrids which not only enriched the germplasm resources of wheat-barley hybrids, but also enriched the dwarf germplasm and had a certain significance in expending the application field of dwarfing genes since the main dwarfing gene of WB29 may be derived from barley and it may be a new dwarf resource.

Key words： Wheat Hordeum vulgare Introgression line Genomic in situ hybridization (GISH) Specific sequence-tagged site (STS) Dwarfing gene Genetic analysis

收稿日期: 2015-03-20 出版日期: 2015-07-24

基金资助:农业部948项目;陕西省自然科学基础研究计划重点项目;陕西省重点科技创新团队计划

通讯作者: 陈新宏 E-mail: cxh2089@126.com

引用本文:

昝凯郑青焕敬樊陈真真白宇浩刘洋王亮明刘淑会王中华陈新宏. 小麦-大麦矮秆渗入系WB29的分子细胞学鉴定及其矮秆遗传特性分析[J]. , 2015, 23(10): 1273-1281.

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http://journal05.magtech.org.cn/Jwk_ny/CN/ 或 http://journal05.magtech.org.cn/Jwk_ny/CN/Y2015/V23/I10/1273

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