不同铝处理下纳米硅矿化沉积对豌豆根边缘细胞耐铝性的影响

doi:10.16258/j.cnki.1674-5906.2025.08.011

生态环境学报 ›› 2025, Vol. 34 ›› Issue (8): 1265-1272.DOI: 10.16258/j.cnki.1674-5906.2025.08.011

不同铝处理下纳米硅矿化沉积对豌豆根边缘细胞耐铝性的影响

冯英明(), 唐娇, 陈醒韵, 郭依唯, 郑雨欣, 田晓, 喻敏^*()

佛山大学农业与生物工程学院园艺系/国际膜生物学与环境研究中心，广东佛山 528200

收稿日期:2024-08-27 出版日期:2025-08-18 发布日期:2025-08-01
通讯作者: *E-mail: yumin@fosu.edu.cn
作者简介:冯英明（1979年生），男，副教授，硕士，主要从事植物逆境生物学研究。E-mail: fyingming@fosu.edu.cn
基金资助:
国家自然科学基金项目(42077150);国家自然科学基金项目(42377042)

Extracellular Silica Nanocoat Confers Aluminum Resistance in Root Tip and Root Border Cells of Pea under Different Aluminum Treatments

FENG Yingming(), TANG Jiao, CHEN Xingyun, GUO Yiwei, ZHENG Yuxin, TIAN Xiao, YU Min^*()

International Research Centre for Environmental Membrane Biology/Department of Horticulture School of Agricultural and Bioengineering, Foshan University, Foshan 528200, P. R. China

Received:2024-08-27 Online:2025-08-18 Published:2025-08-01

摘要/Abstract

摘要：

为探究硅缓解铝毒的生理机制及影响因子，选择豌豆根边缘细胞为模式细胞，通过聚乙烯亚胺诱导细胞壁上纳米硅与活性铝生物矿化形成纳米硅壳，研究氯化铝、硝酸铝和硫酸铝等不同铝溶液处理对纳米硅在根边缘细胞壁上沉积的生理机制及影响。结果表明，1）不同铝条件下纳米硅能提高根边缘细胞活率，减少活性铝进入细胞，降低细胞内活性氧含量水平以及提高线粒体膜电位，其中氯化铝、硝酸铝和硫酸铝膜电位分别升高了25.7%、16.8%和17.3%，减少了铝毒对根边缘细胞的毒害作用。2）不同铝溶液中的酸根离子能影响细胞壁组分的官能团吸收峰强度，在波长3380、2940、1730、1650、1540、1460、1170、1050 cm⁻¹均有特征峰，但纳米硅处理后吸收峰强度降低，表明在铝毒胁迫下纳米硅处理降低了羧基、羟基、羰基的吸收峰强度。3）不同铝条件下均可以在诱导情况下在根边缘细胞壁上形成纳米硅层，且加硅后细胞壁中均有铝硅酸盐的存在。因此，纳米硅在细胞上的矿化沉积能够缓解铝离子毒害作用，离子种类及浓度等能影响根边缘细胞壁组分中官能团的变化以及硅铝沉积结构。

关键词: 豌豆, 铝毒, 纳米硅, 生物硅化, 根边缘细胞

Abstract:

Root border cells (RBCs) of pea were selected as model cells to study the physiological mechanisms and factors influencing silicon alleviation of aluminum (Al) toxicity. Polyvinylimine was used to induce the active biomineralization of aluminum and form nano silicon shells. The physiological mechanisms and effects of different aluminum solutions, such as aluminum chloride, aluminum nitrate, and aluminum sulfate, on the deposition of nano silicon on RBCs walls were studied. The results were as follows: 1) nanosilica can increase the cell viability of RBCs, reduce the entry of reactive aluminum into the cells, lower the level of intracellular reactive oxygen species, and increase the mitochondrial membrane potential (the potentials of aluminum chloride, aluminum nitrate, and aluminum sulfate films increased by 25.68%, 16.80%, and 17.33%, respectively) to reduce the toxic effect of aluminum on RBCs under different environmental conditions. 2) Acid ions in different Al solutions can affect the absorption peak intensity of functional groups in cell wall components, with characteristic peaks at 3380, 2940, 1730, 1650, 1540, 1460, 1170, and 1050 cm⁻¹. However, the absorption peak intensity decreased after nano-Si treatment, indicating that under Al toxicity stress, nano-Si treatment reduced the absorption peak intensity of carboxyl, hydroxyl, and carbonyl groups. 3) Under different aluminum conditions, a nanosilicon layer can be formed on the cell wall of RBCs under PEI induction. Therefore, the mineralized deposition of nano silicon on cells can alleviate the toxic effects of Al ions. The type and concentration of ions can affect the changes in functional groups in the cell wall components of RBCs and the structure of silicon aluminum deposition.

Key words: pea, aluminum toxicity, nanosilica, biosilicification, root border cells

中图分类号:

X171.5

冯英明, 唐娇, 陈醒韵, 郭依唯, 郑雨欣, 田晓, 喻敏. 不同铝处理下纳米硅矿化沉积对豌豆根边缘细胞耐铝性的影响[J]. 生态环境学报, 2025, 34(8): 1265-1272.

FENG Yingming, TANG Jiao, CHEN Xingyun, GUO Yiwei, ZHENG Yuxin, TIAN Xiao, YU Min. Extracellular Silica Nanocoat Confers Aluminum Resistance in Root Tip and Root Border Cells of Pea under Different Aluminum Treatments[J]. Ecology and Environmental Sciences, 2025, 34(8): 1265-1272.

图/表 7

图1 无机铝处理下纳米硅对RBCs细胞活率的影响结果取3次独立测试的平均值（mean±SD；n=3），不同小写字母表示同一时期不同处理组间差异显著（p<0.05），下同

Figure 1 Effect of nano silicon on the viability of RBCs under inorganic aluminum treatmen

图2 无机铝处理下纳米硅对RBCs活性铝的影响

Figure 2 Effect of nano silicon on active aluminum content of RBCs under inorganic aluminum treatment

图3 无机铝处理下纳米硅对RBCs活性氧的影响

Figure 3 Effect of nano silicon on reactive oxygen content of RBCs under inorganic aluminum treatment

图4 无机铝处理下纳米硅对RBCs线粒体膜电位的影响 590nm J-aggregate为聚合体通道；525 nm Monomer为单体通道；Merge为复合通道

Figure 4 Effect of nano silicon on mitochondrial membrane potential of RBCs under inorganic aluminum treatment

图5 无机铝处理下纳米硅对RBCs傅里叶红外光谱分析

Figure 5 Fourier transform infrared spectrum analysis of RBCs by nano silicon under inorganic aluminum treatment

表1 细胞壁傅里叶红外光谱波长对应吸收峰的官能团归属和物质来源

Table 1 Functional groups and material sources of absorption peaks corresponding to the wavelength of Fourier transform infrared spectrum of cell wall

波长/cm⁻¹	功能基团	化合物来源
3380	−OH和N−H伸缩振动	蛋白质、纤维素、半纤维素等
2930	C−H伸缩振动	蛋白质、纤维素、果胶
1730	C=O	果胶中酯类化合物、蛋白质酰胺I带
1660	−COOR	果胶中酯类化合物、蛋白质酰胺I带
1540	N−H的弯曲振动和 C−N的伸缩振动	蛋白质酰胺II带
1450	N−H的弯曲振动和 C−N的伸缩振动	蛋白质酰胺II带
1380	饱和C−H的弯曲振动	纤维素
1170	C−O−C伸缩振动	纤维素
1050	C−O的伸缩振动	碳水化合物如纤维素等的糖链

图6 无机铝处理下纳米硅对RBCs细胞壁的硅铝结构分析

Figure 6 Silicon-aluminum structure analysis of nano silicon on RBCs cell wall under inorganic aluminum treatment

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不同铝处理下纳米硅矿化沉积对豌豆根边缘细胞耐铝性的影响

Extracellular Silica Nanocoat Confers Aluminum Resistance in Root Tip and Root Border Cells of Pea under Different Aluminum Treatments

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