植物硒吸收转化机制及生理作用研究进展

doi:10.13287/j.1001-9332.201612.037

摘要/Abstract

摘要： 硒是大多微生物、动物及人类的必要微量元素,但其在植物生长发育中的生理作用至今存在争议.较低浓度硒具有促进植物生长、提高植物耐受能力的功能,而大部分植物在高浓度下表现出中毒现象.随着人类对摄入硒及环境硒污染问题的认识加深,作物硒生物强化与硒污染植物修复问题引起重视,推动了对硒在植物中的吸收积累及代谢调控的研究.近年来对植物硒吸收及转化的研究表明,不同硒水平下植物对硒吸收积累及生理响应存在差异,土壤环境因素对植物硒吸收及转化具有重要影响,对高聚硒植物硒代谢研究逐渐揭示出硒在植物体内的转化过程和调控机理等.本文总结了目前硒生物强化与植物修复方面的研究进展,对环境中硒分布特点、植物硒吸收及其影响因素、植物体内硒转化及其过程调控关键酶,以及硒在植物中的生理作用等进行了综述,并对植物硒生理及分子机制未来研究方向进行展望.

Abstract: Selenium (Se) is an essential nutrient for many organisms, including microbe, animal and human, but the Se uptake and transformation mechanisms and physiological roles in plant still are controversial until now. Se could improve the growth and tolerance of plant at an appropriate le-vel, but could be toxic at higher levels. Research concerning Se uptake and metabolism in plant were promoted by Se biofortification and Se phytoremediation induced by the issues of Se deficiency in food and Se pollution in special areas. Recently, the results of Se uptake and transformation in plant have indicated that there are significant differences of Se accumulation and physiological roles in various plants and significant influence of soil conditions on Se uptake of plant. In addition, the process of Se metabolism in Se hyperaccumulators and its regulation were revealed gradually with the studies on improvement of Se uptake in plant. According to the results of Se biofortification in crop and Se phytoremediation so far, we summarized the advances in the studies with the reference to Se distribution in environment, the detail process of Se uptake, key regulators of transformation and its physiological roles in plant. We hope this can provide a novel insight to further research upon Se in plant.

姜英, 曾昭海, 杨麒生, 赵杰, 杨亚东, 胡跃高. 植物硒吸收转化机制及生理作用研究进展[J]. 应用生态学报, 2016, 27(12): 4067-4076.

JIANG Ying, ZENG Zhao-hai, YANG Qi-sheng, ZHAO Jie, YANG Ya-dong, HU Yue-gao. Selenium (Se)uptake and transformation mechanisms and physiological function in plant: A review[J]. Chinese Journal of Applied Ecology, 2016, 27(12): 4067-4076.

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