不同栽培措施对紫苏镉富集能力的影响

肖清铁; 郑新宇; 韩永明; 朱静静; 郑梅琴; 吕荣海; 林瑞余

doi:10.19303/j.issn.1008-0384.2018.07.014

不同栽培措施对紫苏镉富集能力的影响

doi: 10.19303/j.issn.1008-0384.2018.07.014

肖清铁^{1, 2,},
郑新宇^{1, 2},
韩永明¹,
朱静静¹,
郑梅琴^{1, 2},
吕荣海³,
林瑞余^{1, 2, ,}

1.
福建省农业生态过程与安全监控重点实验室/福建农林大学生命科学学院, 福建福州 350002
2.
作物生态与分子生理学福建省高校重点实验室, 福建福州 350002
3.
福建省上杭县农业技术推广站, 福建上杭 364000

基金项目:

国家重点研发计划项目 2017YFD0800900

福建省自然科学基金项目 2009J01056

福建省自然科学基金项目 2013J01083

福建省自然科学基金项目 2015J01081

详细信息

作者简介:
肖清铁(1987-), 男, 助理实验师, 研究方向:农业生态学(E-mail:weizhen87@163.com)

通讯作者:
林瑞余(1968-), 男, 教授, 研究方向:农业生态学(E-mail:lrylin2004@163.com)

中图分类号: S567.21
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- 被引次数: 0
出版历程
- 收稿日期: 2018-05-12
- 修回日期: 2018-06-30
- 刊出日期: 2018-07-01

Cd-Uptake of Perilla frutescens (L.)Britt as Affected by Cultivation Conditions

XIAO Qing-tie^{1, 2
,},
ZHENG Xin-yu^{1, 2},
HAN Yong-ming¹,
ZHU Jing-jing¹,
ZHENG Mei-qin^{1, 2},
LÜ Rong-hai³,
LIN Rui-yu^{1, 2
, ,}

1.
Fujian Provincial Key Laboratory of Agroecological Processing and Safety Monitoring/College of Life Sciences, Fujian Agriculture and Forestry, University, Fuzhou, Fujian 350002, China
2.
Key Laboratory of Crop Ecology and Molecular Physiology of Fujian Province University, Fuzhou, Fujian 35002, China
3.
Agro-technical Extension Station of Shanghang County in Fujian Province, Shanghang, Fujian 364000, China

摘要

摘要: 为探讨种植密度、施肥及种植方式对紫苏镉富集能力的影响，通过田间随机区组试验，分析了不同栽培措施下紫苏各部位的镉含量及镉富集总量。结果表明，种植密度和种植方式显著影响紫苏不同部位镉的吸收和积累，施肥方式显著影响紫苏茎叶和籽粒中镉的吸收和积累。低密度种植D1（行株距30 cm×20 cm）和移栽种植方式（P1）可提高紫苏地上部及全株镉含量，施用有机肥（F1）可提高紫苏籽粒镉含量。镉迁移系数（TF）和富集系数（BCF）随种植密度的增大而减小，移栽紫苏的TF和BCF高于直播紫苏。低密度、移栽种植处理的紫苏镉含量（4.57~5.08 mg·kg^-1）、TF（1.43~1.75）和BCF（2.08~2.24）均处于最高水平。低密度（D1）和高密度栽培D3（行株距20 cm×20 cm）紫苏镉富集总量无差异，均显著高于中密度D2（行株距25 cm×20 cm）栽培紫苏镉富集总量。田间栽培条件下镉在紫苏不同部位的分配比例：茎叶>根部>籽粒，其中地上部的平均分配比为83.11%。总之，混合施肥促进直播紫苏镉富集，施用复合肥有利于移栽紫苏镉向地上部迁移，适宜的高密度可提高紫苏对镉污染土壤的修复效率。
- 紫苏 /
- 栽培 /
- 镉 /
- 富集 /
- 植物修复
Abstract: Effects of planting density, fertilization and other cultivation conditions on the Cd uptake of Perilla frutescens(L.) Britt was studied under a randomized block field experiment. Both density and starting from sowed seeds or transplanted seedlings of the planting practices were found to significantly affect the uptake and accumulation in parts of the plant.Fertilization exerted a significant effect on the uptake in the seeds. A high content of Cd was found in the entire plant when P. frutescens was started by transplanting seedlings (P1) with a low planting density (i.e., at row and plant spacings of 30 cm×20 cm) (D1), and in the seeds by applying organic fertilizer (F1). The Cd translocation factor (TF) and bioconcentration factors (BCF) of the plants decreased as the planting density increased. They were higher for the transplanted than the seeded P. frutescens. Thus, the maximum Cd content (i.e., 4.57-5.08 mg·kg^-1), TF(i.e., 1.43-1.75) and BCF(2.08-2.24) of P. frutescens were observed when the plants were transplanted from seedlings and allowed adequate space to grow. The Cd accumulation did not differ significantly between D1 and planting spacing of 20 cm×20 cm(D3). However, both D1 and D3 yielded plants with significantly higher Cd than if the spacing was 25 cm×20 cm (D2). Cd in the above-ground stems and leave saccounted for 83.11% of the entire plant and was higher than the under-ground roots, while the seeds had the least.It appeared that organic fertilizer promoted Cd uptake in the seeded plants, while compound fertilizer benefited the Cd translocating to the above-ground plant parts, and appropriate planting density facilitated the phytoremediation of Cd-contaminated soil.
- Perilla frutescens (L.)Britt /
- cultivating method /
- cadmium /
- accumulation /
- phytoremediation

HTML全文

图 1 不同处理紫苏镉迁移系数和富集系数

*注：图中小写字母代表不同处理间的差异显著性(P＜0.05)。

Figure 1. Cd TF and BCF of P. frutescens under different treatments

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图 2 不同处理紫苏镉分配比

Figure 2. Cd distribution in parts of P. frutescens under different treatments

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表 1 紫苏不同部位镉含量方差分析

Table 1. ANOVA on Cd contents in parts of P. frutescens

因素	根	茎叶	籽粒	地上部	全株	迁移系数TF	富集系数BCF
D	0.00	0.00	0.00	0.00	0.00	0.00	0.00
F	0.21	0.35	0.00	0.13	0.07	0.20	0.13
P	0.00	0.00	0.00	0.00	0.00	0.00	0.00
D*F	0.00	0.03	0.28	0.03	0.01	0.13	0.03
D*P	0.03	0.00	0.55	0.00	0.00	0.00	0.00
F*P	0.89	0.01	0.26	0.01	0.01	0.29	0.01
DFP	0.00	0.00	0.00	0.00	0.01	0.00	0.00

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表 2 不同处理紫苏镉含量

Table 2. Cd contents of P. frutescens under different treatments

[单位/(mg·kg^-1)]
处理	根	茎叶	籽粒	地上部	全株
D1F1P1	3.73±0.36bcdef^*	5.54±0.35a	4.17±0.34ab	5.30±0.26a	5.08±0.24a
D1F1P2	3.85±0.19bcde	3.46±0.19bc	4.72±0.83a	3.57±0.19b	3.62±0.19b
D1F2P1	3.03±0.27fgh	5.41±0.54a	4.19±0.87ab	5.27±0.55a	4.88±0.43a
D1F2P2	3.11±0.36efg	3.45±0.31bc	3.66±0.45bc	3.48±0.32bc	3.41±0.27bc
D1F3P1	3.15±0.35defg	5.22±0.48a	2.41±0.04efg	4.91±0.41a	4.57±0.26a
D1F3P2	4.21±0.28b	2.77±0.38cde	3.71±0.28bc	2.84±0.34de	3.1±0.22cd
D2F1P1	1.91±0.36i	2.49±0.24de	2.32±0.33efg	2.47±0.24de	2.36±0.16fg
D2F1P2	3.88±0.54bcd	2.44±0.44de	3.65±0.54bc	2.56±0.4de	2.84±0.29def
D2F2P1	1.97±0.24i	2.19±0.45de	1.99±0.62fg	2.17±0.46e	2.13±0.42g
D2F2P2	2.96±0.40gh	2.24±0.06de	3.34±0.53bcd	2.36±0.10de	2.46±0.08fg
D2F3P1	2.37±0.40hi	2.51±0.58de	2.49±0.09def	2.51±0.49de	2.48±0.46fg
D2F3P2	2.77±0.61gh	2.57±0.32de	2.15±0.18efg	2.53±0.28de	2.57±0.15defg
D3F1P1	3.93±0.38bc	2.18±0.39de	2.60±0.39def	2.22±0.39de	2.52±0.32efg
D3F1P2	3.75±0.52bcdef	2.91±0.15cd	3.04±0.20cde	2.93±0.16cd	3.07±0.08cde
D3F2P1	3.71±0.24bcdef	4.00±0.78b	2.51±0.59def	3.86±0.75b	3.84±0.65b
D3F2P2	4.88±0.60a	2.10±0.33e	2.61±0.13def	2.15±0.29e	2.65±0.17defg
D3F3P1	3.33±0.29cdefg	2.94±0.22cd	1.59±0.59g	2.77±0.13de	2.86±0.15def
D3F3P2	4.13±0.47b	2.25±0.07de	2.80±0.17def	2.32±0.05de	2.62±0.08defg
注：同列数据后无相同小写字母代表处理间镉含量的差异达显著水平(P＜0.05)，表 4同。

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表 4 不同处理紫苏镉富集总量

Table 4. Cd-accumulation in P. frutescens under different treatments

[单位/(g·hm^-2)]
处理	根	茎叶	籽粒	地上部	全株
D1F1P1	4.26±0.78g	30.79±3.13ab	4.98±0.74a	35.77±3.30a	40.04±4.01abcd
D1F1P2	5.87±0.51fg	24.09±2.03bcde	3.18±0.57bcd	27.28±2.46bcdef	33.15±2.96defgh
D1F2P1	4.24±0.75g	30.71±3.39ab	2.94±0.64bcde	33.64±3.94abc	37.88±3.74abcdef
D1F2P2	6.25±1.11fg	26.08±1.84bcde	3.92±0.51b	30.01±2.21abcdef	36.26±2.39abcdefg
D1F3P1	4.55±0.39g	28.7±3.53abcd	1.66±0.23f	30.36±3.76abcdef	34.91±3.63cdefgh
D1F3P2	10.67±1.69b	28.39±3.27abcd	2.7±0.56cdef	31.09±2.8abcde	41.76±1.66abc
D2F1P1	4.34±1.02g	20.96±2.68ef	1.9±0.39ef	22.85±2.64fg	27.19±3.01hi
D2F1P2	6.86±1.35ef	14.71±3.37f	2.53±0.5cdef	17.25±3.68g	24.10±4.18i
D2F2P1	4.30±0.56g	21.85±4.77de	2.61±1.02cdef	24.46±5.65defg	28.76±6.21ghi
D2F2P2	6.29±1.37fg	19.99±1.23ef	3.43±0.75bcd	23.43±1.82efg	29.71±2.95fghi
D2F3P1	4.32±1.09g	19.51±4.92ef	3.22±0.32bcd	22.73±4.81fg	27.06±5.62hi
D2F3P2	7.76±1.82cdef	28.71±3.24abcd	2.21±0.18def	30.93±3.28abcde	38.68±1.93abcde
D3F1P1	8.56±0.40cde	20.1±3.36ef	2.84±0.39bcdef	22.94±3.73fg	31.5±3.34efghi
D3F1P2	9.47±1.42bc	28.94±2.15abcd	5.28±0.63a	34.22±2.35ab	43.69±1.94a
D3F2P1	7.27±1.08def	33.53±8.79a	2.25±0.86def	35.77±9.39a	43.04±10.39abc
D3F2P2	14.79±0.95a	25.37±4.77bcde	3.27±0.49bcd	28.64±4.9abcdef	43.43±4.18ab
D3F3P1	7.06±1.24ef	29.35±3.66abc	2.25±0.65def	31.6±3.25abcd	38.66±4.43abcde
D3F3P2	9.20±0.52bcd	22.27±1.96cde	3.69±1.1bc	25.95±2.7cdef	35.15±2.73bcdefgh

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表 3 紫苏不同部位镉富集总量、分配比方差分析

Table 3. Variance analysis on Cd-accumulation and distribution in parts of P. frutescens

因素	镉富集总量					镉分配比
因素	根	茎叶	籽粒	地上部	全株	根	茎叶	籽粒
D	0.00	0.00	0.01	0.00	0.00	0.00	0.00	0.19
F	0.12	0.04	0.00	0.14	0.07	0.67	0.05	0.00
P	0.00	0.08	0.00	0.26	0.12	0.00	0.00	0.01
D*F	0.00	0.18	0.00	0.13	0.05	0.00	0.60	0.00
D*P	0.47	0.26	0.00	0.26	0.35	0.65	0.60	0.01
F*P	0.01	0.11	0.42	0.19	0.18	0.07	0.04	0.04
DFP	0.00	0.00	0.00	0.00	0.00	0.00	0.00	0.00

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