中国农业科学 ›› 2015, Vol. 48 ›› Issue (1): 10-22.doi: 10.3864/j.issn.0578-1752.2015.01.02

• 作物遗传育种·种质资源 • 上一篇    下一篇

多环境下野生大豆染色体片段代换系群体农艺性状相关QTL/片段的鉴定

向仕华,王吴彬,何庆元,杨红燕,刘成,邢光南,赵团结,盖钧镒   

  1. 南京农业大学大豆研究所/国家大豆改良中心/农业部大豆生物学与遗传育种重点实验室(综合)/作物遗传与种质创新国家重点实验室,南京 210095
  • 收稿日期:2014-06-11 出版日期:2015-01-01 发布日期:2015-01-01
  • 通讯作者: 盖钧镒,E-mail:sri@njau.edu.cn
  • 作者简介:向仕华,E-mail:xsh444333@yeah.net;王吴彬,E-mail:soybeanwang@163.com。向仕华和王吴彬为同等贡献作者。
  • 基金资助:
    国家重点基础研究发展计划(973计划)项目(2011CB1093)、国家公益性行业(农业)科研专项经费项目(201203026-4)、国家自然科学基金(31260332)、长江学者和创新团队发展计划(PCSIRT13073)、教育部高等学校创新引智计划项目(B08025)、江苏省优势学科建设工程专项(PAPD)、江苏省现代作物生产协同创新中心项目(JCIC-MCP)、作物遗传与种质创新国家重点实验室自主课题

Identification of QTL/Segments Related to Agronomic Traits Using CSSL Population Under Multiple Environments

XIANG Shi-hua, WANG Wu-bin, HE Qing-yuan, YANG Hong-yan, LIU Cheng, XING Guang-nan, ZHAO Tuan-jie, GAI Jun-yi   

  1. Soybean Research Institute, Nanjing Agricultural University/National Center for Soybean Improvement/MOA Key Laboratory for Biology and Genetic Improvement of Soybean (General) / National Key Laboratory of Crop Genetics and Germplasm Enhancement, Nanjing 210095
  • Received:2014-06-11 Online:2015-01-01 Published:2015-01-01

摘要: 【目的】改进染色体片段代换系群体,挖掘野生大豆(Glycine soja Sieb. et Zucc.)中蕴藏的农艺性状优异等位变异,为拓宽栽培大豆(Glycine max (L.) Merr.)的遗传基础提供材料和依据。【方法】通过标记加密和剔除部分单标记型片段的方法,改进以野生大豆N24852为供体,栽培大豆NN1138-2为受体的染色体片段代换系(CSSL)群体SojaCSSLP1;对改进后的群体(SojaCSSLP2)进行3年2点田间试验,通过单标记分析、区间作图、完备复合区间作图和基于混合线性模型的复合区间作图等4种定位方法,结合与轮回亲本有显著差异的染色体片段代换系间相互比对,检测与大豆开花期、株高、主茎节数、单株荚数、百粒重和单株粒重相关的野生片段。【结果】改进后的群体(SojaCSSLP2)由150个CSSL构成,其中,有130个家系与SojaCSSLP1相同;在原遗传图谱上,新增40个SSR标记,相邻标记间平均遗传距离由16.15 cM变为12.91 cM,大于20 cM的区段由32个减少至17个,标记覆盖遗传距离总长度较原图谱(2 063.04 cM)增加103.52 cM;群体NN1138-2背景回复率变幅为79.45%—99.70%,平均为94.62%。利用SojaCSSLP2群体,分别鉴定到与开花期、株高、主茎节数、单株荚数、百粒重和单株粒重相关的4、5、5、7、14和3个工作QTL(working QTL)/片段,其中有15个工作QTL/片段能在多个环境下检测到,属共性工作QTL(joint working QTL);除片段Sct_190—Sat_293上的主茎节数位点外,野生等位变异具有的加性效应方向与双亲表型差异方向一致;单个位点分别能解释5%—64%的表型变异;同时,分别检测到3、2和2个与地点存在互作的株高、主茎节数和单株荚数QTL/片段,其中与凤阳环境的互作均具有增加表型的效应,这可能与凤阳较南京所处纬度高有关;这些位点/片段分布在26个染色体片段上,其中有7个片段与2个及以上性状相关,可能是性状相关的遗传基础;与前人结果比较,有3个开花期、3个株高、2个主茎节数、2个单株荚数、8个百粒重、2个单株粒重位点能在其他遗传背景栽培大豆中检测到,说明在这些位点上野生大豆和栽培大豆间及栽培大豆间均存在遗传差异;另外18个位点(片段)为本研究利用野生大豆的新发现。【结论】大豆开花期、株高和主茎节数的遗传基础较百粒重简单,前者均存在效应较大位点/片段,后者多由小效应位点控制,遗传基础极为复杂;野生大豆中蕴藏着新的等位变异,能拓宽栽培大豆遗传基础。

关键词: 野生大豆(Glycine soja Sieb. et Zucc.), 栽培大豆(Glycine max (L.) Merr.), 染色体片段代换系(CSSL), 农艺性状

Abstract: 【Objective】 The present study was aimed to take a first step of the improvement of the previously reported chromosome segment substitution line (CSSL) population SojaCSSLP1, and to explore superior QTL/gene-alleles related to some agronomic traits from the wild parent (Glycine soja Sieb. et Zucc.) for broadening the genetic basis of cultivated soybean (Glycine max (L.) Merr.). 【Method】 The SojaCSSLP1, with the wild soybean N24852 as donor parent and the cultivated soybean NN1138-2 as recurrent parent, was treated with adding markers and removing a number of lines with segment of single marker, the new population was designated as SojaCSSLP2. By using the new population, the QTL/segments for flowering time (FT), plant height (PH), node number (NN), pod number per plant (PN), 100-seed weight (100SW) and seed weight per plant (PSW) were detected through joint comparisons among CSSLs significantly different from the recurrent parent based on QTL mapping with the methods of single marker analysis (SMA), interval mapping (IM), inclusive composite interval mapping (ICIM) and mixed linear composite interval mapping (MCIM), for experiments in three years each with two locations. 【Result】SojaCSSLP2 was composed of 150 CSSLs, of which 130 ones were the same as SojaCSSLP1, added 40 new SSR markers into the previous molecular map, resulted in the average genetic distance and the number of lines with genetic distance more than 30 cM between adjacent markers reduced from 16.15 cM and 32 to 12.91 cM and 17, respectively. The total length of the genetic map increased by 103.52 cM in comparison to the original map (2 063.04 cM). The genome component of NN1138-2 in CSSLs ranged from 79.45% to 99.70% with an average of 94.62% in SojaCSSLP2. Tested in three years and two locations, 4, 5, 5, 7, 14 and 3 working QTL/segments were identified for FT, PH, NN, PN, 100SW and PSW, respectively, with the improved population. Of those, 15 QTL/segments were joint working QTL which could be detected in more than one environment. The directions of additive effects for wild alleles were consistent with that expected from the parental phenotypes except segment of Sct_190-Sat_293 for NN. Among the QTL, the individual QTL could explain 5% to 64% of the phenotypic variation. There were 3, 2 and 2 QTL/fragments that interacted with locations for PH, NN and NP, respectively, and the interactions associated with Fengyang could increase the value of phenotype, which may be due to its higher latitude than that of Nanjing. These detected loci distributed on 26 substituted segments, among them seven related to more than one trait, which might be the genetic basis of correlation among the traits. Compared with the results in the literature, 3, 3, 2, 2, 8 and 2 QTL could also be detected in other cultivated soybeans for FT, PH, NN, 100SW and PSW, respectively, indicating allele differentiation happened not only between wild and cultivated but also among cultivated soybeans. The other 18 loci/segments were newly discovered in the wild soybean.【Conclusion】 The genetic base of FT, PH and NN are much simpler than that of 100SW. There was a large effect QTL (PV<10%) in the former, while the later is controlled by many small effect loci (PV<10%) with complicated genetic bases. Using the wild soybean, the novel alleles with the capability of broadening the genetic base of cultivated soybean can be explored.

Key words: wild soybean (Glycine soja Sieb. et Zucc.), cultivated soybean (Glycine max (L.) Merr.), chromosome segment substitution line (CSSL), agronomic trait