期刊文献+

水稻糙米重金属Cd^(2+)含量的QTL分析 被引量:5

Mapping of QTLs of Cd^(2+) content in brown rice under Cd^(2+) stress in rice
下载PDF
导出
摘要 镉(Cd2+)是一种分布较广泛、毒性较强的一种重金属,文章利用韭菜青×IR26杂交衍生的一个重组自交系群体(Recombinant inbred lines,RIL)及构建的SSR分子遗传图谱,对控制糙米中Cd2+含量的QTL进行分析,为选育籽粒中Cd2+低吸收或低积累的水稻品种提供参考。结果表明,在Cd2+胁迫(5mg/kg)处理条件下,共检测到2个与糙米Cd2+含量有关的QTLs,分别位于水稻第11染色体上的标记RM6288-RM6544和RM167-RM5704之间,其中qCCBR-11a对表型贡献率为11.17%,加性效应0.089;qCCBR-11b对表型变异贡献率为7.66%,加性效应0.075。相关分析显示,糙米Cd2+含量与株高、每穗总粒数、每穗实粒数、结实率和千粒重等产量性状的相关性均不显著,糙米中Cd2+含量是一个相对独立、由基因控制的遗传性状。 A population of F8 recombinant inbred lines(RILs),derived from a cross between IR26(Oryza sativa L.spp. indica)and Jiucaiqing(japonica),were used to identify the quantitative trait loci(QTLs)for Cd^2+content in brown rice under 5 mg/kg Cd^2+stress.Two QTLs,qCCBR-11a and qCCBR-11b,associated with the Cd2+content in brown rice,were detected on chromosome 11.qCCBR-11a was located at the position between markers RM6288 and RM6544,accounting for 11.17% of the phenotypic variance with an additive effect value of 0.089. qCCBR-11b at the interval between markers RM167 and RM5704 explained 7.66% of the phenotypic variance with an additive effect value of 0.075. In addition, the correlation coefficients between Cd^2+ content of brown rice and plant height, spikelets per panicle, filled grains per panicle, seed setting rate, and 1 000-grain weight were not significant. This suggested that the Cd^2+ content in brown rice under Cd^2+ stress was an independent genetic trait.
出处 《遗传》 CAS CSCD 北大核心 2009年第11期1135-1140,共6页 Hereditas(Beijing)
基金 江苏省农业三项工程项目(编号:SX(2006)123)资助
关键词 水稻 Cd^2+胁迫 糙米Cd^2+含量 QTL定位 rice(Oryza sativa L.) Cd2+stress Cd2+content in brown rice QTLs mapping
  • 相关文献

参考文献28

  • 1Giordani C, Cecchi S, Zanchi C. Phytoremediation of soil polluted by nickel using agricultural crops. Environ Manag, 2005, 36(5): 675-681.
  • 2程旺大,姚海根,吴伟,张国平.土壤-水稻体系中的重金属污染及其控制[J].中国农业科技导报,2005,7(4):51-54. 被引量:71
  • 3顾继光,林秋奇,胡韧,诸葛玉平,周启星.土壤—植物系统中重金属污染的治理途径及其研究展望[J].土壤通报,2005,36(1):128-133. 被引量:173
  • 4赵步洪,张洪熙,奚岭林,朱庆森,杨建昌.杂交水稻不同器官镉浓度与累积量[J].中国水稻科学,2006,20(3):306-312. 被引量:85
  • 5Tudoreanu L, Phillips CJC. Modeling cadmium uptake and accumulation in plants. Adv Agron, 2004, 84:121-157.
  • 6Kirkham MB. Cadmium in plants on polluted soils: Effects of soil factors, hyperaccumulation, and Amendments. Geoderma, 2006, 137: 19-32.
  • 7Rubio M I, Escrig I, Martinez-Cortina C, Lopez-Benet F J, Sanz A. Cadmium and nickel accumulation in rice plants. Effects on mineral nutrition and possible interactions of abscisic and gibberellic acids. Plant Growth Regul, 1994, 14(2): 151-157.
  • 8沈圣泉,庄杰云,舒小丽,包劲松,夏英武.水稻幼苗耐Al^(3+)胁迫的QTL定位分析[J].作物学报,2006,32(4):479-483. 被引量:7
  • 9Wang YX, Wu P, Wu YR, Yan XL. Molecular marker malysis of manganese toxicity tolerance in rice under greenhouse conditions. Plant Soil, 2002, 238(2): 227-233.
  • 10Wu P, Hu B, Liao CY, Zhu JM, Wu YR, Senadhira D, Paterson A. Characterization of tissue tolerance to iron by molecular markers in different lines of rice. Plant Soil, 1998, 203(2): 217-226.

二级参考文献196

共引文献593

同被引文献82

引证文献5

二级引证文献22

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部