玉米发芽过程重金属镉中毒机理研究

Research on cadmium toxicity mechanism during maize germination

  • 摘要: 为了深入探讨重金属胁迫下植物重金属代谢过程及机理, 采用有一定重金属镉耐受能力的农作物玉米为试验材料, 综合研究了不同镉浓度(5~100 μmol·L-1)及不同处理时间下玉米幼苗发芽、不同组织部位镉含量及分布、镉中毒前后液相色谱 质谱联用谱图(HPLC-MS)、核磁共振氢谱图(1H NMR)和总蛋白氨基酸含量。结果表明, 低于50 μmol·L-1的镉浓度能促进玉米发芽, 高于此浓度可明显抑制发芽。镉在胚乳、根、茎、芽等新鲜组织部位的分布不均, 其分布情况为: 胚乳>根>茎>芽。HPLC-MS和1H NMR分析结果表明, 玉米中镉以金属螯合剂(PC)形式络合。总蛋白氨基酸含量分析说明镉胁迫影响营养物质的吸收及合成。重金属镉在整个玉米幼苗中传输积累过程为: 大量镉吸附在胚乳中, 部分直接吸附在根表面; 部分镉以游离形式存在, 部分以植物金属螯合剂螯合形式存在; 镉在细胞中与各种蛋白作用, 在胞液、液泡、胞间连丝等细胞器间传递; 镉经根、茎传输到芽, 此过程主要受浓度梯度影响; 镉的传输过程很可能遵循顺浓度梯度的协助扩散过程, 试验证明了此过程的合理性。

     

    Abstract: To explore the mechanism of heavy metal metabolism in plants under heavy metal stress, maize tolerance to cadmium (Cd) was investigated as a test case. Maize seedling was germinated under different Cd concentrations (5~100 μmol·L-1) and the processing time was studied. The parameters of maize seedling, Cd content and distribution in different tissues, High Performance Liquid Chromatography-Mass Spectrometry spectra (HPLC-MS), Nuclear Magnetic Resonance spectra (1H NMR) and amino acids contents were investigated. The results showed that under Cd stress <50 μmol·L-1, maize germination was significantly enhanced. When, however, Cd stress exceeded 50 μmol·L-1, maize germination was inhibited. Cd was unevenly distributed in the fresh endosperm, root, stem and bud tissues in the order of endosperm > radicle > stem > burgeon. HPLC-MS and 1H NMR analyses indicated Cd chelation in maize in the form of phytochelatin (PC). Total protein amino acid content analysis showed that nutrient absorption and synthesis were to some extent affected by Cd stress. Cd accumulation and transmission process in maize seedling was such that while a large amount of Cd was adsorbed on maize endosperm, limited Cd was directly adsorbed on radicle surface. Cd existed in both free and phytochelatin forms in the maize plant. Cd interacted with various cell proteins and was transmitted among cytosol, vacuole, cell plasmodesmata and other seedling organelles. Cd was transmitted to burgeon through the radicle and stem and the transfer process was driven mainly by concentration gradient. The process likely followed along a concentration gradient facilitated by diffusion, and the rationality of which was proven by the experiment.

     

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