谢运河, 纪雄辉, 李莓, 黄涓, 官迪, 田发祥. 籽粒硫苷特性对甘蓝型油菜吸收积累Cd的影响[J]. 中国生态农业学报(中英文), 2015, 23(8): 994-1000. DOI:10.13930/j.cnki.cjea.150224
引用本文: 谢运河, 纪雄辉, 李莓, 黄涓, 官迪, 田发祥. 籽粒硫苷特性对甘蓝型油菜吸收积累Cd的影响[J]. 中国生态农业学报(中英文), 2015, 23(8): 994-1000.DOI:10.13930/j.cnki.cjea.150224
XIE Yunhe, JI Xionghui, LI Mei, HUANG Juan, GUAN Di, TIAN Faxiang. Cd uptake and accumulation of Brassica napusvarieties with different seed glucosinolate characteristics[J]. Chinese Journal of Eco-Agriculture, 2015, 23(8): 994-1000. DOI:10.13930/j.cnki.cjea.150224
Citation: XIE Yunhe, JI Xionghui, LI Mei, HUANG Juan, GUAN Di, TIAN Faxiang. Cd uptake and accumulation ofBrassica napusvarieties with different seed glucosinolate characteristics[J].Chinese Journal of Eco-Agriculture, 2015, 23(8): 994-1000.DOI:10.13930/j.cnki.cjea.150224

籽粒硫苷特性对甘蓝型油菜吸收积累Cd的影响

Cd uptake and accumulation ofBrassica napusvarieties with different seed glucosinolate characteristics

  • 摘要:油菜对Cd的吸收转运不仅受外源S供应的影响, 且与自身S代谢关系非常密切。硫苷是影响油菜品质的重要含S次级代谢产物, 而油菜籽粒硫苷含量能较好地表征油菜的硫苷特性。为了解油菜硫苷特性与油菜吸收积累Cd之间的关联, 通过Cd污染土壤的大田试验, 研究了不同硫苷特性甘蓝型油菜的Cd吸收积累特性。结果表明, 初花期高、低硫苷油菜不同器官间Cd含量皆为根>叶>茎, 成熟期皆为茎>根>壳>籽粒。初花期高硫苷与低硫苷油菜对Cd的吸收积累无显著差异; 而成熟期高硫苷油菜对Cd的吸收积累显著低于低硫苷油菜, 高硫苷油菜成熟期根、茎、壳、籽粒Cd含量分别为3.90 mgkg -1、4.50 mgkg -1、0.97 mgkg -1、0.17 mgkg -1, 低硫苷油菜则分别为4.57 mgkg -1、5.20 mgkg -1、1.32 mgkg -1、0.29 mgkg -1, 比高硫苷油菜分别高17.18% ( P<0.05)、15.56%( P<0.05)、36.08%( P<0.05)、70.59%( P<0.05)。成熟期高硫苷油菜壳/茎、籽粒/壳Cd转运系数分别为0.22和0.17, 而低硫苷油菜分别为0.25和0.23, 比高硫苷油菜分别高13.64%( P<0.05)和35.29% ( P<0.05)。高硫苷油菜显著抑制了Cd从茎向其上位器官(壳、籽粒)的转运。研究结果还表明, 低硫苷油菜与高硫苷油菜对污染土壤Cd的单季净化率分别仅为0.90%和0.76%, 作为修复Cd污染土壤的富集植物, 其净化效率皆有待提高。

    Abstract:Cd uptake and translocation of rape ( Brassica napus) are affected not only by exogenous S supply, but also closely related with its S metabolism. Glucosinolate is an important S-containing secondary metabolite, and its content of rape seed can well characterize the glucosinolate characteristics of rape. The relationship between seed glucosinolate characteristics and Cd uptake and accumulation by rape was investigated through a field experiment in Cd contaminated soils to explore Cd uptake of rape varieties with different glucosinolate characteristics of seed. The results showed that the orders of Cd contents in different organs of the two types of rapes (high-glucosinolate and low-glucosinolate) were the same, root > leaf > stem at early blooming stage and stem > root > shell > seed at mature stage. There were no significant differences between high-glucosinolate rapes and low-glucosinolate rapes in uptake and accumulation of Cd at early blooming stage, while the Cd uptake and accumulation of high-glucosinolate rapes were lower than thoes of low-glucosinolate rapes at mature stage. The Cd contents of root, stem, shell, seed were 3.90 mgkg -1, 4.50 mgkg -1, 0.97 mgkg -1, 0.17 mgkg -1in the high-glucosinolate rape. They were 4.57 mgkg -1, 5.20 mgkg -1, 1.32 mgkg -1, 0.29 mgkg1 in the low-glucosinolate rape, which were 17.18% ( P< 0.05), 15.56% ( P< 0.05), 36.08% ( P< 0.05) and 70.59% ( P< 0.05) higher than the former, respectively. The high-glucosinolate rapes could restrain Cd transfer from stem to the superior organs (shell and seed). The translation coefficients of Cd from stem to shell (shell/stem) and from shell to seed (seed/shell) were significantly different between two types of rape, which were 0.22 and 0.17 in the high-glucosinolate rapes, 0.25 and 0.23 in the low-glucosinolate rapes at mature stage, respectively. The purifying rate of soil Cd was 0.90% for the low-glucosinolate rapes and 0.76% for the high-glucosinolate rapes. As the enrichment plant in Cd contaminated soils, the purification ability of rapes need to be improved.

/

    返回文章
    返回