Tolerance and vegetation restoration prospect of seedlings of five oak species for Pb/Zn mine tailing

doi:10.13287/j.1001-9332.201912.039

Abstract

Abstract: A pot experiment was conducted to evaluate the growth response and vegetation restoration prospect of seedlings of five oak species for the phytoremediation of lead/zinc (Pb/Zn) mine tailings. Seedlings of Quercus imbricaria, Q. coccinea, Q. pagoda, Q. shumardii, Q. fabri were transplanted into pots containing Pb/Zn mine tailings to comparatively examine their biomass, root morphology, absorption and transfer characteristics of nutrient elements and heavy metals 30 months later. The results showed that all the seedlings could survive in the Pb/Zn tailings after 30 months. The biomass of Q. coccinea and Q. fabri decreased in Pb/Zn tailings compared with the control, while no significant difference were found for other three species. Compared with the control, root biomass was increased to some extent in Pb/Zn tailings except Q. coccinea. The lateral root morphological parameters were reduced only for Q. coccinea . Under heavy metal stress, nutrient concentrations of root and stem of oak seedlings did not change compared with the control. Generally, the concentrations of heavy metals in plant tissues were low, and the values of bioconcentration factor (BCF) and translocation factor (TF) were less than 1. Q. pagoda could accumulate more Cd, with concentrations of 22.4 and 15.1 mg·kg^-1 in leaf and stem, respectively, and could translocate more Cd from root to shoot with TF of 2.3. Our results suggested that the seedlings of tested oak species could be used as the potential species for contaminated soil. Q. shumardii had the highest tole-rance with a low BCF and TF, implying that they were better potential candidates for afforestation and ecological restoration of mine tailings.

SHI Xiang, WANG Shu-feng, CHEN Yi-tai, XU Qin-di, SUN Hai-jing, AN Ran, LU Xiao-hong, LU Yan, FAN Sui-jun. Tolerance and vegetation restoration prospect of seedlings of five oak species for Pb/Zn mine tailing[J]. Chinese Journal of Applied Ecology, 2019, 30(12): 4091-4098.

References

[1] Marques APGC, Moreira H, Rangel AOSS, et al. Arsenic, lead and nickel accumulation in Rubus ulmifolius growing in contaminated soil in Portugal. Journal of Hazardous Materials, 2009, 165: 174-179
[2] Parra A, Zornoza R, Conesa E, et al. Seedling emergence, growth and trace elements tolerance and accumulation by Lamiaceae species in a mine soil. Chemosphere, 2014, 113: 132-140
[3] Bhargava A, Carmona FF, Bhargava M, et al. Approaches for enhanced phytoextraction of heavy metals. Journal of Environmental Management, 2012, 105: 103-120
[4] Hu P-J (胡鹏杰), Li Z (李柱), Zhong D-X (钟道旭), et al. Research progress on the phytoextraction of heavy metal contaminated soils in China. Plant Physiology Journal (植物生理学报), 2014, 50(5): 577-584 (in Chinese)
[5] Mendez MO, Maier RM. Phytostabilization of mine tailings in arid and semiarid environments: An emerging remediation technology. Environmental Health Perspectives, 2008, 116: 278-283
[6] Monterroso C, Rodríguez F, Chaves R, et al. Heavy metal distribution in mine-soils and plants growing in a Pb/Zn-mining area in NW Spain. Applied Geochemistry, 2014, 44: 3-11
[7] Zhang X, Zhu YG, Zhang YB, et al. Growth and metal uptake of energy sugarcane (Saccharum spp.) in diffe-rent metal mine tailings with soil amendments. Journal of Environmental Sciences, 2014, 26: 1080-1089
[8] Pérez-Esteban J, Escoléstico C, Ruiz-Fernández J, et al. Bioavailability and extraction of heavy metals from contaminated soil by Atriplex halimus. Environmental and Experimental Botany, 2013, 88: 53-59
[9] Bian FY, Zhong ZK, Zhang XP, et al. Phytoremedia-tion potential of moso bamboo (Phyllostachys pubescens) intercropped with Sedum plumbizincicola in metal-contaminated soil. Environmental Science and Pollution Research, 2017, 24: 27244-27253
[10] Acosta JA, Abbaspour A, Martínez GR, et al. Phytoremediation of mine tailings with Atriplex halimus and organic/inorganic amendments: A five-year field case study. Chemosphere, 2018, 204: 71-78
[11] Pottier M, García de la Torre VS, Victor C, et al. Geno-typic variations in the dynamics of metal concentrations in poplar leaves: A field study with a perspective on phytoremediation. Environmental Pollution, 2015, 199: 73-82
[12] Zhou LY, Zhao Y, Wang SF, et al. Lead in the soil-mulberry (Morus alba L.)-silkworm (Bombyx mori) food chain: Translocation and detoxification. Chemosphere, 2015, 128: 171-177
[13] Salam MMA, Kaipiainen E, Mohsin M, et al. Effects of contaminated soil on the growth performance of young Salix (Salix schwerinii E. L. Wolf) and the potential for phytoremediation of heavy metals. Journal of Environmental Management, 2016, 183: 467-477
[14] Gogorcena Y, Larbi A, Andaluz S, et al. Effects of cadmium on cork oak (Quercus suber L.) plants grown in hydroponics. Tree Physiology, 2011, 31: 1401-1412
[15] Evangelou MWH, Robinson BH, Gunthardt-Goerg MS, et al. Metal uptake and allocation in trees grown on contaminated land: Implications for biomass production. International Journal of Phytoremediation, 2013, 15: 77-90
[16] Prasad MNV, Freitas H. Removal of toxic metals from solution by leaf, stem and root phytomass of Quercus ilex L. (holly oak). Environmental Pollution, 2000, 110: 277-283
[17] Domínguez MT, Madrid F, Marañón T, et al. Cadmium availability in soil and retention in oak roots: Potential for phytostabilization. Chemosphere, 2009, 76: 480-486
[18] Zhao XL, Zheng LY, Xia XL, et al. Responses and acclimation of Chinese cork oak (Quercus variabilis Bl.) to metal stress: The inducible antimony tolerance in oak trees. Environmental Science and Pollution Research, 2015, 22: 11456-11466
[19] Shi X, Wang SF, Sun HJ, et al. Comparative of Quercus spp. and Salix spp. for phytoremediation of Pb/Zn mine tailings. Environmental Science and Pollution Research, 2017, 24: 3400-3411
[20] Ministry of Ecology and Environment of China (中华人民共和国生态环境部), State Administration for Market Regulation (国家市场监督管理总局). Soil Environment Quality Risk Control Standard for Soil Contamination of Agricultural Land (GB 15618-2018) [EB/OL]. (2018-08-01)[2019-01-25]. http://bz.mee.gov.cn/bzwb/trhj/trhjzlbz/201807/t20180703_446029.shtml (in Chinese)
[21] Leng H-N (冷华妮), Chen Y-T (陈益泰), Duan H-P (段红平), et al. Effects of phosphorus stress on the growth and nitrogen and phosphorus absorption of diffe-rent Formosan sweet gum provenances. Chinese Journal of Applied Ecology (应用生态学报), 2009, 20(4): 754-760 (in Chinese)
[22] Li R (李然), Xu Y-M (徐应明), Wang L (王林), et al. Effects of different manganese treatments on heavy metals accumulation and root morphology of two cultivars of Brassica chinensis under cadmium stress. Asian Journal of Ecotoxicology (生态毒理学报), 2018, 13(2): 140-148 (in Chinese)
[23] Guo D, Xia M, Wei X, et al. Anatomical traits associated with absorption and mycorrhizal colonization are linked to root branch order in twenty-three Chinese temperate tree species. New Phytologist, 2008, 180: 673-683
[24] Malar S, Manikandan R, Favas PJC, et al. Effect of lead on phytotoxicity, growth, biochemical alterations and its role on genomic template stability in Sesbania grandiflora: A potential plant for phytoremediation. Ecotoxicology and Environmental Safety, 2014, 108: 249-257
[25] Wang X-X (王小雪). Response to Cd stress of different families of Hibiscus hamabo Sieb. et Zucc. Master Thesis. Chongqing: Southwest University, 2012 (in Chinese)
[26] Xu ZF, Chen LH, Tang SS, et al. Sex-specific responses to Pb stress in Populus deltoides: Root architecture and Pb translocation. Trees, 2016, 30: 2019-2027
[27] Li J-B (李金波), Li S-G (李诗刚), Song G-L (宋桂龙), et al. Effect of arsenic stress on root morphological parameters and absorption of nutrient elements in ryegrass. Pratacultural Science (草业科学), 2018, 35(6): 1385-1392 (in Chinese)
[28] Wang SF, Shi X, Sun HJ, et al. Variations in metal tolerance and accumulation in three hydroponically cultivated varieties of Salix integra treated with lead. PLoS One, 2014, 9(9): e108568
[29] Gong Q (公勤), Wang L (王玲), Dai T-W (戴同威), et al. Effects of copper treatment on mineral nutrient absorption and cell ultrastructure of spinach seedlings. Chinese Journal of Applied Ecology (应用生态学报), 2019, 30(3): 941-950 (in Chinese)
[30] Rehman S, Ghulam A, Muhammad S, et al. Effect of salinity on cadmium tolerance, ionic homeostasis and oxidative stress responses in conocarpus exposed to cadmium stress: Implications for phytoremediation. Ecotoxicology and Environmental Safety, 2019, 171: 146-153
[31] Luo ZB, He JL, Polle A, et al. Heavy metal accumulation and signal transduction in herbaceous and woody plants: Paving the way for enhancing phytoremediation efficiency. Biotechnology Advances, 2016, 34: 1131-1148
[32] Liu W-T (刘维涛), Zhang Y-L (张银龙), Chen Z-M (陈喆敏), et al. Cadmium and zinc absorption and distribution in various tree species in a mining area. Chinese Journal of Applied Ecology (应用生态学报), 2008, 19(4): 752-756 (in Chinese)
[33] Bolan N, Kunhikrishnan A, Thangarajan R, et al. Remediation of heavy metal(loid)s contaminated soils: To mobilize or to immobilize? Journal of Hazardous Materials, 2014, 266: 141-166
[34] Inman JC, Parker GR. Decomposition and heavy metal dynamics of forest litter in Northwestern Indiana. Environmental Pollution, 1978, 17: 39-51
[35] Tang CF, Chen YH, Zhang QN, et al. Effects of peat on plant growth and lead and zinc phytostabilization from lead-zinc mine tailing in southern China: Screening plant species resisting and accumulating metals. Ecotoxicology and Environmental Safety, 2019, 176: 42-49
[36] de Souza SCR, de Andrade SAL, de Souza LA, et al. Lead tolerance and phytoremediation potential of Brazi-lian leguminous tree species at the seedling stage. Journal of Environmental Management, 2012, 110: 299-307
[37] Huang Y-Z (黄益宗), Zhu Y-G (朱永官). A review on cadmium contamination in forest ecosystem. Acta Ecologica Sinica (生态学报), 2004, 24(1): 101-108 (in Chinese)
[38] Mendez MO, Maier RM. Phytoremediation of mine tailings in temperate and arid environments. Reviews in Environmental Science and Bio/Technology, 2008, 7: 47-59
[39] Zeng P, Guo ZH, Xiao XY, et al. Phytoextraction potential of Pteris vittata L. co-planted with woody species for As, Cd, Pb and Zn in contaminated soil. Science of the Total Environment, 2019, 650: 594-603
[40] Zeng P, Guo ZH, Xiao XY, et al. Complementarity of co-planting a hyperaccumulator with three metal(loid)- tolerant species for metal(loid)-contaminated soil remediation. Ecotoxicology and Environmental Safety, 2019, 169: 306-315