土壤镉胁迫对甘薯品质和镉、锌吸收的影响

刘兰英; 吕新; 陈丽华; 黄薇; 涂杰峰; 余华; 上官亮; 谢亚兴

doi:10.19303/j.issn.1008-0384.2019.03.014

土壤镉胁迫对甘薯品质和镉、锌吸收的影响

doi: 10.19303/j.issn.1008-0384.2019.03.014

1.
福建省农业科学院农业质量标准与检测技术研究所, 福建福州 350003
2.
中纺检测福建有限公司, 福建泉州 362000

基金项目:

福建省自然科学基金项目 2018J01037

福建省科技计划项目——省属公益类科研院所基本科研专项 2018R1018-4

福建省农业科学院科技创新团队建设项目 STIT2017-1-12

详细信息

作者简介:
刘兰英(1987-), 女, 硕士, 助理研究员, 研究方向:产地环境与农产品质量安全(E-mail:lly87119@126.com)

通讯作者:
涂杰峰(1960-), 男, 研究员, 研究方向:产地环境与农产品质量安全(E-mail:tujiefeng@hotmail.com)

中图分类号: S531
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出版历程
- 收稿日期: 2019-02-11
- 修回日期: 2019-02-28
- 刊出日期: 2019-03-28

Cd and Zn Uptakes and Quality of Sweet Potatoes under Cd-stress

1.
Institute for Agricultural Standards and Testing Technology, Fujian Academy of Agricultural Science, Fuzhou, Fujian 350003, China
2.
Textile Inspection Company Limited, Fujian Province, Quanzhou, Fujian 362000, China

摘要

摘要: 目的揭示土壤镉污染对甘薯品质及镉、锌吸收能力的影响。方法通过盆栽试验，分析不同镉水平胁迫下甘薯产量、营养品质及镉、锌吸收的变化，同时采用迁移系数分析镉、锌在土壤-甘薯系统中的迁移转化特性。结果随着土壤镉处理浓度的增加，甘薯块根产量呈下降趋势，最大程度可降低32.6%；块根果肉中蛋白质指标受影响程度较大，含量显著下降，最大程度可降低32.1%。镉胁迫会显著增加土壤和甘薯植株各部位的镉含量，但会抑制块根果肉对锌的吸收。种植甘薯可在一定程度上降低土壤中的镉含量，甘薯属于低镉吸收作物，当镉处理质量浓度不超过5 mg·kg^-1时，块根果肉中镉含量基本低于国家安全限量标准（GB 2762-2017食品中污染物限量标准，Cd ≤ 0.1 mg·kg^-1）。甘薯不同部位镉含量高低顺序为柴根>茎段>块根皮部>叶片>块根果肉，其中柴根和茎段部位对镉的迁移能力较大，镉主要富集在柴根部位。结论在镉污染程度不高的土壤中，可以通过种植甘薯来富集镉，同时柴根部位对镉的截留可以减少镉通过食物链向人体迁移。
- 甘薯 /
- 镉 /
- 锌 /
- 营养品质 /
- 吸收能力
Abstract: Objective Uptakes of Cd and Zn by sweet potato plants from Cd polluted soil was investigated. Method A pot experiment was conducted on the sweet potato to study the effects of Cd-stress on the yield, nutritional quality as well as the Cd and Zn uptakes of the plants. Migration and transformation of Cd and Zn from soil to plants were analyzed. Result The tuber yield of the plants decreased with increasing Cd in soil. It maximized at a reduction of 32.6%. The food quality of the tubers was greatly affected by the stress with a reduction on proteins as high as 32.1%. Cd-stress significantly increased the Cd concentrations in various parts of a plant land the soil, and inhibited the Zn absorption by the tubers. Sweet potato plants are not highly capable in absorbing Cd and can only reduce Cd in soil to a limited extent. Thus, so long as Cd in soil was less than 5 mg·kg^-1, the tubers grown on it were basically safe for consumption as the Cd content in tuber would likely be below the national standard for safety (Cd ≤ 0.1 mg·kg^-1). The Cd accumulations in parts of a plant were found to rank in the order of roots > stems > peel > leaves > flesh.The migration and transformation abilities of root and stem for Cd were higher, making Cd mainly accumulated in root. Conclusion Planting sweet potatoes could help mitigate the pollution effect only in soils not heavily contaminated with Cd. By eliminating the more Cd-concentrated roots on a tuber for food, risks on health could be largely avoided.
- sweet potato /
- Cd /
- Zn /
- nutritional quality /
- uptake ability

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图 1 镉处理下甘薯块根产量的变化

注：图中无相同小写字母表示各处理间差异显著(P < 0.05)。图 2~4同。

Figure 1. Effect of Cd concentration on tuber yield of sweet potato plants

Note: Data with different lowercase letters indicate significant differences at P < 0.05.The same for Fig. 2-4.

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图 2 镉处理下甘薯块根营养品质的变化

Figure 2. Effect of Cd concentration on nutritional quality of sweet potatoes

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图 3 镉胁迫下甘薯土壤镉、锌含量的变化

Figure 3. Contents of Cd and Zn in soils under Cd-stress

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图 4 镉胁迫下甘薯块根果肉镉、锌含量的变化

Figure 4. Contents of Cd and Zn in tuber flesh of sweet potato plants under Cd-stress

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表 1 镉胁迫下甘薯各部位镉、锌的含量变化

Table 1. Contents of Cd and Zn in parts of tuber of sweet potato plants under Cd-stress

[单位/(mg·kg^-1)]
元素 Elements	植株各部位 Parts of plant	处理 Treatments
元素 Elements	植株各部位 Parts of plant	Cd 0	Cd 5	Cd 10	Cd 20
镉Cd	柴根Root	0.61±0.011d	22.80±0.306c	51.90±0.360b	125.00±0.909a
	块根皮部Root peel	0.23±0.016d	1.47±0.071c	6.07±0.036b	13.40±0.106a
	块根果肉Root pulp	0.08±0.036d	0.70±0.089c	1.48±0.078b	3.31±0.044a
	茎段Stem	0.28±0.013d	5.58±0.102c	12.50±0.051b	20.70±0.089a
	叶片Leaf	0.15±0.055d	0.60±0.068c	1.55±0.112b	3.07±0.133a
锌Zn	柴根Root	33.40±0.192a	29.10±0.203ab	27.00±0.335bc	25.30±0.213c
	块根皮部Root peel	17.10±0.133a	17.70±0.331a	17.40±0.051a	17.70±0.639a
	块根果肉Root pulp	11.50±0.058a	10.10±0.088ab	9.64±0.208ab	8.56±0.197b
	茎段Stem	17.60±0.112d	19.70±0.336c	22.20±0.057b	26.50±0.133a
	叶片Leaf	51.50±0.103a	50.80±0.180a	51.70±0.403a	52.30±0.354a
注：同行数据后无相同小写字母者表示处理间差异显著(P < 0.05)，表 2同。 Note: Data with different lowercase letters on a same row indicate significant differences at P < 0.05. Same for Table 2.

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表 2 镉胁迫下甘薯镉、锌的迁移系数

Table 2. Translocation factors of Cd and Zn on sweet potato plants under Cd-stress

元素 Elements	迁入部位 Immigration part	迁移系数Transfer factors
元素 Elements	迁入部位 Immigration part	Cd 0	Cd 5	Cd 10	Cd 20
镉Cd	柴根Root	5.06±0.113	6.43±0.107	9.81±0.88	10.60±0.776
	块根皮部Root peel	0.37±0.005	0.06±0.004	0.12±0.012	0.11±0.001
	块根果肉Root pulp	0.36±0.030	0.48±0.004	0.24±0.001	0.25±0.004
	茎段Stem	3.39±0.096	7.91±0.179	8.45±0.275	6.25±0.316
	叶片Leaf	0.55±0.031	0.11±0.024	0.12±0.020	0.15±0.014
锌Zn	柴根Root	0.27±0.053	0.29±0.014	0.26±0.008	0.23±0.035
	块根皮部Root peel	0.51±0.014	0.61±0.003	0.64±0.014	0.70±0.001
	块根果肉Root pulp	0.67±0.055	0.57±0.010	0.55±0.014	0.48±0.030
	茎段Stem	1.53±0.195	1.95±0.044	2.30±0.128	3.10±0.164
	叶片Leaf	2.93±0.106	2.58±0.077	2.33±0.012	1.97±0.042

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