化学
镉
生物利用度
细菌
食品科学
环境化学
吸附
生物化学
生物量(生态学)
硫化镉
生物物理学
下调和上调
土壤水分
戒毒(替代医学)
微生物
生物炭
激发子
污染物
生物累积
作者
Li Zhang,Nan Zhao,Ajit K. Sarmah,Lijie Zhao,Qiang Zeng,Jian Sun,Yu Du,Jianmin Li,Yuepeng La,Dasong Lin,R Wang
标识
DOI:10.1021/acs.jafc.6c03745
摘要
Effective and sustainable strategies to reduce cadmium (Cd) accumulation in leafy vegetables grown on alkaline soils remain limited. Here, mercapto-modified nanosilica (MS) was developed and evaluated for mitigating Cd uptake in pak choi. MS3 exhibited an 11-fold higher Cd adsorption capacity than unmodified nanosilica, attributed to strong chemisorption via mercapto groups. Soil incorporation (0.1% w / w ), irrigation (800 mg·L –1 ), and foliar spraying (100 mg·L –1 ) of MS3 significantly reduced Cd concentrations in edible tissues by 59.9%, 64.7%, and 43.8%, respectively, while increasing leaf biomass by 24.5%–38.1%. Soil- and irrigation-applied MS3 decreased bioavailable Cd and enriched beneficial bacteria ( Lysobacter, Sphingomonas ). Transcriptomic analysis revealed that MS3 enhanced Cd detoxification by upregulating photosynthesis and cell wall synthesis genes and modulating transporters (downregulating HIPP and COPT to inhibit Cd uptake, while upregulating HMA5, ABCG40, and MTP to promote vacuolar sequestration). These findings highlight MS3 as a promising nanotechnology for ensuring crop safety in Cd-contaminated alkaline soils.
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