Plant growth and Cd accumulation characteristics in different planting modes of maize and Amaranthus hypochondriacus.

doi:10.13287/j.1001-9332.201909.038

Abstract

Abstract: To achieve the goal of remediation while producing for farmland contaminated by Cd, maize and grain amaranth (Amaranthus hypochondriacus) were planted on farmland contaminated by Cd in five different intercropping modes, including alternating wide-narrow-row of maize and single-row grain amaranth intercropped between wide rows (T₁), alternating wide-narrow-row of maize and double-row grain amaranth intercropped between wide rows (T₂), equidistant double-row maize and single-row grain amaranth intercropped between rows (T₃), equidistant double-row maize and double-row grain amaranth intercropped between rows (T₄), maize and grain amaranth intercropped with equal four rows (T₅), while maize (CK₁) and grain amaranth (CK₂) single planted as control to explore the effects of different intercropping modes on growth and Cd accumulation of crops and hyper-accumulation plants (A. hypochondriacus). The results showed that: 1) Compared with mono-culture (CK₁), grain yield of maize per plant showed an increasing trend in intercropping modes. The grain yield of maize in T₁ increased by 10.5%, while that in T₄ and T₅ decreased by 6.3% and 5.4% respectively, and that in T₂ or T₃ did not change compared with monoculture of maize. The aboveground biomass per plant and yield per unit area of grain amaranth decreased by 69.5%-95.7% and 83.9%-96.9% in intercropping modes respectively compared with monoculture (CK₂). 2) The Cd content of maize grain showed an increasing trend in intercropping modes compared with monoculture (CK₁). The Cd content of grain amaranth showed a decreasing trend in intercropping modes compared with monoculture (CK2). 3) Compared with monoculture (CK2), the enrichment coefficient, transport coefficient, and effective transport coefficient of grain amaranth all showed an increasing trend in intercropping modes, while the aboveground Cd extraction amount per plant and per unit area of grain amaranth decreased by 40.4%-86.7% and 70.4%-88.9% in intercropping modes, respectively. The total amount of Cd extraction per unit area of maize and grain amaranth in intercropping modes was significantly higher than that in monoculture of maize and lower than that in monoculture of grain amaranth. 4) The content of available Cd in maize rhizosphere soil and the content of total/available Cd in grain amaranth rhizosphere soil both showed an increasing trend in intercropping modes compared with monoculture of both crop, but it had no significant effect on non-rhizosphere soil. In this study, T₁ was beneficial to increase maize grain yield, while T₅ was beneficial to maximize the Cd extraction amount of grain amaranth.

GUO Nan, CHI Guang-yu, SHI Yi, CHEN Xin. Plant growth and Cd accumulation characteristics in different planting modes of maize and Amaranthus hypochondriacus.[J]. Chinese Journal of Applied Ecology, 2019, 30(9): 3164-3174.

References

[1] Vaalgamaa S, Conley DJ. Detecting environmental change in estuaries: Nutrient and heavy metal distributions in sediment cores in estuaries from the Gulf of Finland, Baltic Sea. Estuarine, Coastal and Shelf Science, 2008, 76: 45-56
[2] Gupta DK, Chatterjee S, Datta S, et al. Role of phosphate fertilizers in heavy metal uptake and detoxification of toxic metals. Chemosphere, 2014, 108: 134-144
[3] Chen Q-R (陈炳睿), Xu C (徐超), Lv G-M (吕高明), et al. Effects of nine kinds of curing agents on lead, cdmium, copper, zinc stabilization in the tested soil. Journal of Agro-Environment Science (农业环境科学学报), 2012, 31(7): 1330-1336 (in Chinese)
[4] Yang C (杨辰). Review on remediation and safety utilization of heavy metal pollution of farmland soil in China. Modern Agricultural Science and Technology (现代农业科技), 2017(3): 164-167 (in Chinese)
[5] Yuan Z-Q (袁中强), Cao C-S (曹春香), Bao D-M (鲍达明), et al. Inversion on contents of heavy metals in soils of wetlands in Zoigê Plateau based on remote sensing data. Wetland Science (湿地科学), 2016, 14(1): 113-116 (in Chinese)
[6] Fan T (樊霆), Ye W-L (叶文玲), Chen H-Y (陈海燕), et al. Review on contamination and remediation technology of heavy metal in agricultural soil. Ecology and Environmental Sciences (生态环境学报), 2013, 22(10): 1727-1736 (in Chinese)
[7] Lageman R. Electrore clamation application in the Nether-lands. Environmental Science and Technology, 1993, 27: 2648-2650
[8] Peng JF, Song YH, Yuan P, et al. The remediation of heavy metals contaminated sediment. Journal of Hazar-dous Materials, 2009, 161: 633-640
[9] Salt DE, Blaylock M, Nan Dakumar PA, et al. Phytoremediation: A novel strategy for the removal of toxic metals from the environment using plants. Nature Biotechnology, 1995, 13: 468-474
[10] Ling H (凌辉), Xie S-B (谢水波), Tang Z-P (唐振平), et al. Remediation of heavy metal polluted soil and application for typical Soils. Sichuan Environment (四川环境), 2012, 31(1): 118-122 (in Chinese)
[11] Ali H, Khan E, Sajad MA. Phytoremediation of heavy metals-concepts and applications. Chemosphere, 2013, 91: 869-881
[12] Hao HZ, Zhong RH, Miao YR, et al. The intercrop-ping influence on heavy metal uptake for hyperaccumulators. International Conference on Biomedical Engineering and Biotechnology, Washington DC, USA, 2012: 1826-1828
[13] Gong Z-T (龚子同), Chen H-Z (陈鸿昭), Zhang G-L (张甘霖), et al. Characteristics of soil resources and problems of food security in China. Ecology and Environment (生态环境), 2005, 14(15): 783-788 (in Chinese)
[14] Li Y-M (李颖明), Wang X (王旭), Hao L (郝亮), et al. An analysis on treatment of heavy-metal soil contamination: Characteristics and determinants of far-mers’ treatment methods. China Rural Economy (中国农村经济), 2017(1): 58-67, 95 (in Chinese)
[15] Wei Z-B (卫泽斌), Guo X-F (郭晓方), Qiu J-R (丘锦荣), et al. Innovative technologies for soil remediation: Intercropping or co-cropping. Journal of Agro-Environment Science (农业环境科学学报), 2010, 29(Suppl.1): 267-272 (in Chinese)
[16] Wu QT, Samake M, Mo CH, et al. Simultaneous sludge stabilization and metal removal by metal hy hyper-accumulatorplants. Transactions of 17th World Congress of Soil Science, Bangkok, Thailand, 2002
[17] Li N-Y (李凝玉), Li Z-A (李志安), Jing Y-Z (丁永祯), et al. Effects of intercropping different crops with maize on the Cd uptake by maize. Chinese Journal of Applied Ecology (应用生态学报), 2008, 19(6): 1369-1373 (in Chinese)
[18] Qin L (秦丽), Zhan F-D (湛方栋), Zu Y-Q (祖艳群), et al. Accumulation characteristics of Pb, Cd and Zn by Chenopodium ambrosioides L. intercropping with maize and broad bean. Journal of Yunnan Agricultural University (云南农业大学学报), 2017, 32(1): 153-160 (in Chinese)
[19] Zhao Y (赵颖), Liu L-J (刘利军), Dang J-H (党晋华), et al. Effects of intercropping different crops with maize on its uptake of the PAHs and heavy metal. Environmental Engineering (环境工程), 2014, 32(7): 138-141 (in Chinese)
[20] Chaney RL, Brown SL, Li YM, et al. Potential use of metal hyperaccumulators. Mining Environmental Mana-gement, 1995, 3: 9-11
[21] Fu Y-H (付玉豪), Li F-M (李凤梅), Guo S-H (郭书海), et al. Cadmium pollution in soil and rice plants in Zhangyizhan Town of Zhangshi irrigation area of Shenyang. Chinese Journal of Ecology (生态学杂志), 2017, 36(7): 1965-1972 (in Chinese)
[22] Li N-Y (李凝玉), Lu H-P (卢焕萍), Li Z-A (李志安). Tolerance and accumulation of cadmium in soil by Amaranthus hypochondriacus L. Chinese Journal of Applied and Environmental Biology (应用与环境生物学报), 2010, 16(1): 028-032 (in Chinese)
[23] Li Y (李元), Fang Q-X (方其仙), Zu Y-Q (祖艳群). Accumulation characteristics of two ecotypes Sonchus asper (L.) Hill. to Cd. Acta Botanica Boreali-Occidentalia Sinica (西北植物学报), 2008, 28(6): 1150-1154 (in Chinese)
[24] Tan J-B (谭建波), Chen X (陈兴), Guo X-H (郭先华), et al. Distribution characteristics of Pb and Cd in different parts of sonchus asper and zea mays in an intercropping system. Ecology and Environmental Scien-ces (生态环境学报), 2015, 24(4): 700-707 (in Chinese)
[25] Yu C-B (余长兵), Sun J-H (孙建好), Li L (李隆). Effect of interspecific interaction on crop growth an nutrition accumulation. Plant Nutrition and Fertilizer Science (植物营养与肥料学报), 2009, 15(1): 1-8 (in Chinese)
[26] Chen J-J (陈建军), Xiu H (修珩), Li Y (李元). Absorption and accumulation of Pb with Arabis alpina L. and Zea mays in intercropping system. Environmental Science & Technology (环境科学与技术), 2016, 11(39): 63-78 (in Chinese)
[27] Qin H (秦欢), He Z-J (何忠俊), Xiong J-F (熊俊芬), et al. Effects of intercropping on the contents and accumulation of heavy metals in maize varieties and Pteris cretica L. Journal of Agro-Environment Science (农业环境科学报), 2012, 31(7): 1281-1288 (in Chinese)
[28] Hao Y-R (郝艳茹), Lao X-R (劳秀荣), Sun W-H (孙伟红), et al. Interaction of roots and rhizosphere in the wheat-maize intercropping system. Rural Eco-Environment (农村生态环境), 2003, 19(4): 18 (in Chinese)
[29] Chen Y-X (陈英旭), Lin Q (林琦), Lu F (陆芳), et al. Study on detoxication of organic acid to raddish under the stress of Pb and Cd. Acta Scientiae Circumstantiae (环境科学学报), 2000, 20(4): 467-472 (in Chinese)
[30] Chang X-X (常学秀), Duan C-Q (段昌群), Wang H-X (王焕校). Root excretion and plant resistance to metal toxicity. Chinese Journal of Applied Ecology (应用生态学报), 2000, 11(2): 315-320 (in Chinese)
[31] Liang K-M (梁开明), Fu L (傅玲), Zhang J-E (章家恩), et al. Responses of PSⅡ chlorophyll fluorescence under Cd stress and characteristics of Cd accumulation in Thalia dealbata and rice mono- and inter-cropping systems. Journal of South China Agricultural University (华南农业大学学报), 2014, 35(4): 35-41 (in Chinese)
[32] Li T-X (李廷轩), Ma G-R (马国瑞), Zhang X-Z (张锡洲). Root exudates of potassium-enrichment genotype grain amaranth and their activation on soil mineral potassium. Chinese Journal of Applied Ecology (应用生态学报), 2006, 17(3): 368-372 (in Chinese)
[33] Wang J-G (王金贵), Lyu J-L (吕家珑), Zhang R-L (张瑞龙), et al. Effects of temperature on the adsorption kinetics of cadmium in typical agricultural soils. Journal of Agro-Environment Science (农业环境科学报), 2012, 31(6): 1118-1123 (in Chinese)
[34] Li XH, Zhou QX, Wei SH, et al. Adsorption and desorption of carbendazim and cadmium in typical soils in northeastern China as affected by temperature. Geoderma, 2011, 160: 347-354
[35] Wang X-H (王学华), Dai L (戴力). Immobilization effect and its physiology and biochemical mechanism of the cadmium in crop roots. Scientia Agricultura Sinica (中国农业科学), 2016, 49(22): 4323-4241 (in Chinese)
[36] Wang X-J (王晓娟), Wang W-B (王文斌), Yang L (杨龙), et al. Transport pathways of cadmium (Cd) and its regulatory mechanisms in plant. Acta Ecologica Sinica (生态学报), 2015, 35(23): 7921-7929 (in Chinese)
[37] Wang R-F (王荣芬), Qiu E-F (邱尔发), Tang L-Q (唐丽清). Heavy metals distribution in roadside tree trunks under a heavy urban transportation condition. Acta Ecologica Sinica (生态学报), 2014, 34(15): 4212-4222 (in Chinese)
[38] Hu M-H (胡绵好), Yuan J-H (袁菊红), Yang X-E (杨肖娥). Mn-hyperaccumulator and their hyperaccumulating mechanism. Chinese Journal of Soil Science (土壤通报), 2010, 41(1): 248-256 (in Chinese)
[39] She W (佘玮), Cui G-X (崔国贤), Zhao D-B (赵丹博), et al. Cadmium uptake and transportation in two ramie cultivars under zinc and iron deficiency. Journal of Agro-Environment Science (农业环境科学学报), 2014, 33(2): 283-287 (in Chinese)
[40] Hardiman RT, Jacoby B. Absorption and translocation of Cd in bush beans (Phaseolus vulgaris). Physiologia Plantarum, 1984, 61: 670-674
[41] Zhang Y-X (张玉秀), Yu F (于飞), Zhang Y-Y (张媛雅), et al. Uptake, translocation and accumulation of cadmium in plant. Chinese Journal of Eco-Agriculture (中国农业生态学报), 2008, 16(5): 1317-1321 (in Chinese)
[42] Gao X-L (高茜蕾), Zheng R-L (郑瑞伦), Li H-F (李花粉). Effects of transpiration rate and root characteron cadmium absorption by pakchoi cultivars. Chinese Journal of Ecology (生态学杂志), 2010, 29(9): 1794-1798 (in Chinese)
[43] Meng N (孟楠), Wang M (王萌), Chen L (陈莉), et al. Remediation efficiency of Cd polluted soil by intercropping with herbaceous plants. China Environmental Science (中国环境科学), 2018, 38(7): 2618-2624 (in Chinese)
[44] Hu JL, Chan PT, Wu FY, et al. Arbuscular mycorrhizal fungi induce differential Cd and P acquisition by Alfred stonecrop and upland kangkong in an intercropping system. Applied Soil Ecology, 2013, 63: 29-35
[45] Qin L (秦丽), Zu Y-Q (祖艳群), Zhan F-D (湛方栋), et al. Absorption and accumulation of Cd by Sonchus asper L. Hill. and maize in intercropping systems. Journal of Agro-Environment Science (农业环境科学学报), 2013, 32(3): 471-477 (in Chinese)