National Engineering Research Center for Efficient Utilization of Soil and Fertilizer Resources, College of Resources and Environment, Hunan Agricultural University, Hunan, 410128, China.
Ningyuan County Agricultural Comprehensive Service Center, Hunan, 425600, China.
Environ Pollut. 2022 Aug 1;306:119390. doi: 10.1016/j.envpol.2022.119390. Epub 2022 May 2.
Atmospheric deposition of cadmium (Cd) in rice (Oryza sativa L.) has become a major global concern. Foliar uptake allows vegetables to accumulate heavy metals from the atmosphere, but this has rarely been studied in rice. Therefore, this study investigated the Cd accumulation in rice growing at different exposure periods (the tillering, booting, heading, and maturity stages) under a wet deposition of CdCl·2.5HO solution through pot experiments. The Cd concentrations in leaves, roots, husk, brown rice, and leaf structures were analyzed to explore foliar uptake, accumulation, and distribution of Cd in rice tissues at different growth stages. The results showed that wet deposited Cd can be absorbed on the rice leaf surface and remains on the leaves for a long time. The sequence of Cd accumulation in rice tissues was: leaves > brown rice > husk > roots, with leaves accounting for greater than 71.78% of the total accumulation. The accumulation of wet deposited Cd in leaves, husk, and brown rice had large temporal variations between the four typical stages. There was no significant variations in Cd content in roots between different growth stages. Correspondingly, the foliar uptake of Cd was rarely transported from the leaves via the phloem to roots. Conversely, the foliar uptake of Cd was transported upwards to grains. The accumulation of Cd fluctuated with each growth stage, initially increasing and then decreasing at the heading stage and finally reaching a peak at the maturity stage. The highest total accumulation of Cd in both the high and low wet deposition conditions occurred at maturity, resulting in 15.53 and 11.23 μg plant, respectively. These results provide theoretical support for further research into identifying efficient foliar control measures to reduce Cd accumulation and maintain food safety.
大气中镉(Cd)在水稻(Oryza sativa L.)中的沉积已成为一个全球性的主要关注点。叶片吸收使蔬菜能够从大气中积累重金属,但这在水稻中很少被研究。因此,本研究通过盆栽实验,研究了在 CdCl·2.5HO 溶液的湿沉降下,不同暴露期(分蘖、孕穗、抽穗和成熟阶段)水稻对 Cd 的积累情况。分析叶片、根系、壳、糙米和叶片结构中的 Cd 浓度,以探讨 Cd 在不同生长阶段水稻组织中的叶片吸收、积累和分布。结果表明,湿沉降的 Cd 可以被水稻叶片表面吸收,并在叶片上长时间停留。Cd 在水稻组织中的积累顺序为:叶片>糙米>壳>根,叶片占总积累量的 71.78%以上。叶片、壳和糙米中湿沉降 Cd 的积累在四个典型阶段之间存在较大的时间变化。不同生长阶段根系 Cd 含量无显著差异。相应地,Cd 的叶片吸收很少通过韧皮部从叶片运输到根部。相反,Cd 的叶片吸收向上运输到籽粒。Cd 的积累随每个生长阶段而波动,在抽穗期先增加后减少,最终在成熟期达到峰值。在高、低湿沉降条件下,Cd 的总积累量均在成熟期达到最高,分别为 15.53 和 11.23μg plant。这些结果为进一步研究确定有效的叶面控制措施以减少 Cd 积累和保障食品安全提供了理论支持。
